mod cursor; #[cfg(any(test, feature = "test-support"))] pub mod property_test; mod tree_map; pub use cursor::{Cursor, FilterCursor, Iter}; use heapless::Vec as ArrayVec; use rayon::iter::{IndexedParallelIterator, IntoParallelIterator, ParallelIterator as _}; use std::marker::PhantomData; use std::mem; use std::{cmp::Ordering, fmt, iter::FromIterator, sync::Arc}; pub use tree_map::{MapSeekTarget, TreeMap, TreeSet}; use ztracing::instrument; #[cfg(test)] pub const TREE_BASE: usize = 2; #[cfg(not(test))] pub const TREE_BASE: usize = 6; // Helper for when we cannot use ArrayVec::::push().unwrap() as T doesn't impl Debug trait CapacityResultExt { fn unwrap_oob(self); } impl CapacityResultExt for Result<(), T> { fn unwrap_oob(self) { self.unwrap_or_else(|_| panic!("item should fit into fixed size ArrayVec")) } } /// An item that can be stored in a [`SumTree`] /// /// Must be summarized by a type that implements [`Summary`] pub trait Item: Clone { type Summary: Summary; fn summary(&self, cx: ::Context<'_>) -> Self::Summary; } /// An [`Item`] whose summary has a specific key that can be used to identify it pub trait KeyedItem: Item { type Key: for<'a> Dimension<'a, Self::Summary> + Ord; fn key(&self) -> Self::Key; } /// A type that describes the Sum of all [`Item`]s in a subtree of the [`SumTree`] /// /// Each Summary type can have multiple [`Dimension`]s that it measures, /// which can be used to navigate the tree pub trait Summary: Clone { type Context<'a>: Copy; fn zero<'a>(cx: Self::Context<'a>) -> Self; fn add_summary<'a>(&mut self, summary: &Self, cx: Self::Context<'a>); } pub trait ContextLessSummary: Clone { fn zero() -> Self; fn add_summary(&mut self, summary: &Self); } impl Summary for T { type Context<'a> = (); fn zero<'a>((): ()) -> Self { T::zero() } fn add_summary<'a>(&mut self, summary: &Self, (): ()) { T::add_summary(self, summary) } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct NoSummary; /// Catch-all implementation for when you need something that implements [`Summary`] without a specific type. /// We implement it on a `NoSummary` instead of re-using `()`, as that avoids blanket impl collisions with `impl Dimension for T` /// (as we also need unit type to be a fill-in dimension) impl ContextLessSummary for NoSummary { fn zero() -> Self { NoSummary } fn add_summary(&mut self, _: &Self) {} } /// Each [`Summary`] type can have more than one [`Dimension`] type that it measures. /// /// You can use dimensions to seek to a specific location in the [`SumTree`] /// /// # Example: /// Zed's rope has a `TextSummary` type that summarizes lines, characters, and bytes. /// Each of these are different dimensions we may want to seek to pub trait Dimension<'a, S: Summary>: Clone { fn zero(cx: S::Context<'_>) -> Self; fn add_summary(&mut self, summary: &'a S, cx: S::Context<'_>); #[must_use] fn with_added_summary(mut self, summary: &'a S, cx: S::Context<'_>) -> Self { self.add_summary(summary, cx); self } fn from_summary(summary: &'a S, cx: S::Context<'_>) -> Self { let mut dimension = Self::zero(cx); dimension.add_summary(summary, cx); dimension } } impl<'a, T: Summary> Dimension<'a, T> for T { fn zero(cx: T::Context<'_>) -> Self { Summary::zero(cx) } fn add_summary(&mut self, summary: &'a T, cx: T::Context<'_>) { Summary::add_summary(self, summary, cx); } } pub trait SeekTarget<'a, S: Summary, D: Dimension<'a, S>> { fn cmp(&self, cursor_location: &D, cx: S::Context<'_>) -> Ordering; } impl<'a, S: Summary, D: Dimension<'a, S> + Ord> SeekTarget<'a, S, D> for D { fn cmp(&self, cursor_location: &Self, _: S::Context<'_>) -> Ordering { Ord::cmp(self, cursor_location) } } impl<'a, T: Summary> Dimension<'a, T> for () { fn zero(_: T::Context<'_>) -> Self {} fn add_summary(&mut self, _: &'a T, _: T::Context<'_>) {} } #[derive(Clone, Copy, Debug, Default, PartialEq, Eq, PartialOrd, Ord)] pub struct Dimensions(pub D1, pub D2, pub D3); impl<'a, T: Summary, D1: Dimension<'a, T>, D2: Dimension<'a, T>, D3: Dimension<'a, T>> Dimension<'a, T> for Dimensions { fn zero(cx: T::Context<'_>) -> Self { Dimensions(D1::zero(cx), D2::zero(cx), D3::zero(cx)) } fn add_summary(&mut self, summary: &'a T, cx: T::Context<'_>) { self.0.add_summary(summary, cx); self.1.add_summary(summary, cx); self.2.add_summary(summary, cx); } } impl<'a, S, D1, D2, D3> SeekTarget<'a, S, Dimensions> for D1 where S: Summary, D1: SeekTarget<'a, S, D1> + Dimension<'a, S>, D2: Dimension<'a, S>, D3: Dimension<'a, S>, { fn cmp(&self, cursor_location: &Dimensions, cx: S::Context<'_>) -> Ordering { self.cmp(&cursor_location.0, cx) } } /// Bias is used to settle ambiguities when determining positions in an ordered sequence. /// /// The primary use case is for text, where Bias influences /// which character an offset or anchor is associated with. /// /// # Examples /// Given the buffer `AˇBCD`: /// - The offset of the cursor is 1 /// - [Bias::Left] would attach the cursor to the character `A` /// - [Bias::Right] would attach the cursor to the character `B` /// /// Given the buffer `A«BCˇ»D`: /// - The offset of the cursor is 3, and the selection is from 1 to 3 /// - The left anchor of the selection has [Bias::Right], attaching it to the character `B` /// - The right anchor of the selection has [Bias::Left], attaching it to the character `C` /// /// Given the buffer `{ˇ<...>`, where `<...>` is a folded region: /// - The display offset of the cursor is 1, but the offset in the buffer is determined by the bias /// - [Bias::Left] would attach the cursor to the character `{`, with a buffer offset of 1 /// - [Bias::Right] would attach the cursor to the first character of the folded region, /// and the buffer offset would be the offset of the first character of the folded region #[derive(Copy, Clone, Eq, PartialEq, PartialOrd, Ord, Debug, Hash, Default)] pub enum Bias { /// Attach to the character on the left #[default] Left, /// Attach to the character on the right Right, } impl Bias { pub fn invert(self) -> Self { match self { Self::Left => Self::Right, Self::Right => Self::Left, } } } /// A B+ tree in which each leaf node contains `Item`s of type `T` and a `Summary`s for each `Item`. /// Each internal node contains a `Summary` of the items in its subtree. /// /// The maximum number of items per node is `TREE_BASE * 2`. /// /// Any [`Dimension`] supported by the [`Summary`] type can be used to seek to a specific location in the tree. #[derive(Clone)] pub struct SumTree(Arc>); impl fmt::Debug for SumTree where T: fmt::Debug + Item, T::Summary: fmt::Debug, { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { f.debug_tuple("SumTree").field(&self.0).finish() } } impl SumTree { pub fn new(cx: ::Context<'_>) -> Self { SumTree(Arc::new(Node::Leaf { summary: ::zero(cx), items: ArrayVec::new(), item_summaries: ArrayVec::new(), })) } /// Useful in cases where the item type has a non-trivial context type, but the zero value of the summary type doesn't depend on that context. pub fn from_summary(summary: T::Summary) -> Self { SumTree(Arc::new(Node::Leaf { summary, items: ArrayVec::new(), item_summaries: ArrayVec::new(), })) } pub fn from_item(item: T, cx: ::Context<'_>) -> Self { let mut tree = Self::new(cx); tree.push(item, cx); tree } pub fn from_iter>( iter: I, cx: ::Context<'_>, ) -> Self { let mut nodes = Vec::new(); let mut iter = iter.into_iter().fuse().peekable(); while iter.peek().is_some() { let items: ArrayVec = iter.by_ref().take(2 * TREE_BASE).collect(); let item_summaries: ArrayVec = items.iter().map(|item| item.summary(cx)).collect(); let mut summary = item_summaries[0].clone(); for item_summary in &item_summaries[1..] { ::add_summary(&mut summary, item_summary, cx); } nodes.push(SumTree(Arc::new(Node::Leaf { summary, items, item_summaries, }))); } let mut parent_nodes = Vec::new(); let mut height = 0; while nodes.len() > 1 { height += 1; let mut current_parent_node = None; for child_node in nodes.drain(..) { let parent_node = current_parent_node.get_or_insert_with(|| { SumTree(Arc::new(Node::Internal { summary: ::zero(cx), height, child_summaries: ArrayVec::new(), child_trees: ArrayVec::new(), })) }); let Node::Internal { summary, child_summaries, child_trees, .. } = Arc::get_mut(&mut parent_node.0).unwrap() else { unreachable!() }; let child_summary = child_node.summary(); ::add_summary(summary, child_summary, cx); child_summaries.push(child_summary.clone()).unwrap_oob(); child_trees.push(child_node.clone()).unwrap_oob(); if child_trees.len() == 2 * TREE_BASE { parent_nodes.extend(current_parent_node.take()); } } parent_nodes.extend(current_parent_node.take()); mem::swap(&mut nodes, &mut parent_nodes); } if nodes.is_empty() { Self::new(cx) } else { debug_assert_eq!(nodes.len(), 1); nodes.pop().unwrap() } } pub fn from_par_iter(iter: I, cx: ::Context<'_>) -> Self where I: IntoParallelIterator, Iter: IndexedParallelIterator, T: Send + Sync, T::Summary: Send + Sync, for<'a> ::Context<'a>: Sync, { let mut nodes = iter .into_par_iter() .chunks(2 * TREE_BASE) .map(|items| { let items: ArrayVec = items.into_iter().collect(); let item_summaries: ArrayVec = items.iter().map(|item| item.summary(cx)).collect(); let mut summary = item_summaries[0].clone(); for item_summary in &item_summaries[1..] { ::add_summary(&mut summary, item_summary, cx); } SumTree(Arc::new(Node::Leaf { summary, items, item_summaries, })) }) .collect::>(); let mut height = 0; while nodes.len() > 1 { height += 1; nodes = nodes .into_par_iter() .chunks(2 * TREE_BASE) .map(|child_nodes| { let child_trees: ArrayVec, { 2 * TREE_BASE }, u8> = child_nodes.into_iter().collect(); let child_summaries: ArrayVec = child_trees .iter() .map(|child_tree| child_tree.summary().clone()) .collect(); let mut summary = child_summaries[0].clone(); for child_summary in &child_summaries[1..] { ::add_summary(&mut summary, child_summary, cx); } SumTree(Arc::new(Node::Internal { height, summary, child_summaries, child_trees, })) }) .collect::>(); } if nodes.is_empty() { Self::new(cx) } else { debug_assert_eq!(nodes.len(), 1); nodes.pop().unwrap() } } #[allow(unused)] pub fn items<'a>(&'a self, cx: ::Context<'a>) -> Vec { let mut items = Vec::new(); let mut cursor = self.cursor::<()>(cx); cursor.next(); while let Some(item) = cursor.item() { items.push(item.clone()); cursor.next(); } items } pub fn iter(&self) -> Iter<'_, T> { Iter::new(self) } /// A more efficient version of `Cursor::new()` + `Cursor::seek()` + `Cursor::item()`. /// /// Only returns the item that exactly has the target match. #[instrument(skip_all)] pub fn find_exact<'a, 'slf, D, Target>( &'slf self, cx: ::Context<'a>, target: &Target, bias: Bias, ) -> (D, D, Option<&'slf T>) where D: Dimension<'slf, T::Summary>, Target: SeekTarget<'slf, T::Summary, D>, { let tree_end = D::zero(cx).with_added_summary(self.summary(), cx); let comparison = target.cmp(&tree_end, cx); if comparison == Ordering::Greater || (comparison == Ordering::Equal && bias == Bias::Right) { return (tree_end.clone(), tree_end, None); } let mut pos = D::zero(cx); return match Self::find_iterate::<_, _, true>(cx, target, bias, &mut pos, self) { Some((item, end)) => (pos, end, Some(item)), None => (pos.clone(), pos, None), }; } /// A more efficient version of `Cursor::new()` + `Cursor::seek()` + `Cursor::item()` #[instrument(skip_all)] pub fn find<'a, 'slf, D, Target>( &'slf self, cx: ::Context<'a>, target: &Target, bias: Bias, ) -> (D, D, Option<&'slf T>) where D: Dimension<'slf, T::Summary>, Target: SeekTarget<'slf, T::Summary, D>, { let tree_end = D::zero(cx).with_added_summary(self.summary(), cx); let comparison = target.cmp(&tree_end, cx); if comparison == Ordering::Greater || (comparison == Ordering::Equal && bias == Bias::Right) { return (tree_end.clone(), tree_end, None); } let mut pos = D::zero(cx); return match Self::find_iterate::<_, _, false>(cx, target, bias, &mut pos, self) { Some((item, end)) => (pos, end, Some(item)), None => (pos.clone(), pos, None), }; } fn find_iterate<'tree, 'a, D, Target, const EXACT: bool>( cx: ::Context<'a>, target: &Target, bias: Bias, position: &mut D, mut this: &'tree SumTree, ) -> Option<(&'tree T, D)> where D: Dimension<'tree, T::Summary>, Target: SeekTarget<'tree, T::Summary, D>, { 'iterate: loop { match &*this.0 { Node::Internal { child_summaries, child_trees, .. } => { for (child_tree, child_summary) in child_trees.iter().zip(child_summaries) { let child_end = position.clone().with_added_summary(child_summary, cx); let comparison = target.cmp(&child_end, cx); let target_in_child = comparison == Ordering::Less || (comparison == Ordering::Equal && bias == Bias::Left); if target_in_child { this = child_tree; continue 'iterate; } *position = child_end; } } Node::Leaf { items, item_summaries, .. } => { for (item, item_summary) in items.iter().zip(item_summaries) { let mut child_end = position.clone(); child_end.add_summary(item_summary, cx); let comparison = target.cmp(&child_end, cx); let entry_found = if EXACT { comparison == Ordering::Equal } else { comparison == Ordering::Less || (comparison == Ordering::Equal && bias == Bias::Left) }; if entry_found { return Some((item, child_end)); } *position = child_end; } } } return None; } } /// A more efficient version of `Cursor::new()` + `Cursor::seek()` + `Cursor::item()` #[instrument(skip_all)] pub fn find_with_prev<'a, 'slf, D, Target>( &'slf self, cx: ::Context<'a>, target: &Target, bias: Bias, ) -> (D, D, Option<(Option<&'slf T>, &'slf T)>) where D: Dimension<'slf, T::Summary>, Target: SeekTarget<'slf, T::Summary, D>, { let tree_end = D::zero(cx).with_added_summary(self.summary(), cx); let comparison = target.cmp(&tree_end, cx); if comparison == Ordering::Greater || (comparison == Ordering::Equal && bias == Bias::Right) { return (tree_end.clone(), tree_end, None); } let mut pos = D::zero(cx); return match Self::find_with_prev_iterate::<_, _, false>(cx, target, bias, &mut pos, self) { Some((prev, item, end)) => (pos, end, Some((prev, item))), None => (pos.clone(), pos, None), }; } fn find_with_prev_iterate<'tree, 'a, D, Target, const EXACT: bool>( cx: ::Context<'a>, target: &Target, bias: Bias, position: &mut D, mut this: &'tree SumTree, ) -> Option<(Option<&'tree T>, &'tree T, D)> where D: Dimension<'tree, T::Summary>, Target: SeekTarget<'tree, T::Summary, D>, { let mut prev = None; 'iterate: loop { match &*this.0 { Node::Internal { child_summaries, child_trees, .. } => { for (child_tree, child_summary) in child_trees.iter().zip(child_summaries) { let child_end = position.clone().with_added_summary(child_summary, cx); let comparison = target.cmp(&child_end, cx); let target_in_child = comparison == Ordering::Less || (comparison == Ordering::Equal && bias == Bias::Left); if target_in_child { this = child_tree; continue 'iterate; } prev = child_tree.last(); *position = child_end; } } Node::Leaf { items, item_summaries, .. } => { for (item, item_summary) in items.iter().zip(item_summaries) { let mut child_end = position.clone(); child_end.add_summary(item_summary, cx); let comparison = target.cmp(&child_end, cx); let entry_found = if EXACT { comparison == Ordering::Equal } else { comparison == Ordering::Less || (comparison == Ordering::Equal && bias == Bias::Left) }; if entry_found { return Some((prev, item, child_end)); } prev = Some(item); *position = child_end; } } } return None; } } pub fn cursor<'a, 'b, D>( &'a self, cx: ::Context<'b>, ) -> Cursor<'a, 'b, T, D> where D: Dimension<'a, T::Summary>, { Cursor::new(self, cx) } /// Note: If the summary type requires a non `()` context, then the filter cursor /// that is returned cannot be used with Rust's iterators. pub fn filter<'a, 'b, F, U>( &'a self, cx: ::Context<'b>, filter_node: F, ) -> FilterCursor<'a, 'b, F, T, U> where F: FnMut(&T::Summary) -> bool, U: Dimension<'a, T::Summary>, { FilterCursor::new(self, cx, filter_node) } #[allow(dead_code)] pub fn first(&self) -> Option<&T> { self.leftmost_leaf().0.items().first() } pub fn last(&self) -> Option<&T> { self.rightmost_leaf().0.items().last() } pub fn last_summary(&self) -> Option<&T::Summary> { self.rightmost_leaf().0.child_summaries().last() } pub fn update_last( &mut self, f: impl FnOnce(&mut T), cx: ::Context<'_>, ) { self.update_last_recursive(f, cx); } fn update_last_recursive( &mut self, f: impl FnOnce(&mut T), cx: ::Context<'_>, ) -> Option { match Arc::make_mut(&mut self.0) { Node::Internal { summary, child_summaries, child_trees, .. } => { let last_summary = child_summaries.last_mut().unwrap(); let last_child = child_trees.last_mut().unwrap(); *last_summary = last_child.update_last_recursive(f, cx).unwrap(); *summary = sum(child_summaries.iter(), cx); Some(summary.clone()) } Node::Leaf { summary, items, item_summaries, } => { if let Some((item, item_summary)) = items.last_mut().zip(item_summaries.last_mut()) { (f)(item); *item_summary = item.summary(cx); *summary = sum(item_summaries.iter(), cx); Some(summary.clone()) } else { None } } } } pub fn update_first( &mut self, f: impl FnOnce(&mut T), cx: ::Context<'_>, ) { self.update_first_recursive(f, cx); } fn update_first_recursive( &mut self, f: impl FnOnce(&mut T), cx: ::Context<'_>, ) -> Option { match Arc::make_mut(&mut self.0) { Node::Internal { summary, child_summaries, child_trees, .. } => { let first_summary = child_summaries.first_mut().unwrap(); let first_child = child_trees.first_mut().unwrap(); *first_summary = first_child.update_first_recursive(f, cx).unwrap(); *summary = sum(child_summaries.iter(), cx); Some(summary.clone()) } Node::Leaf { summary, items, item_summaries, } => { if let Some((item, item_summary)) = items.first_mut().zip(item_summaries.first_mut()) { (f)(item); *item_summary = item.summary(cx); *summary = sum(item_summaries.iter(), cx); Some(summary.clone()) } else { None } } } } pub fn extent<'a, D: Dimension<'a, T::Summary>>( &'a self, cx: ::Context<'_>, ) -> D { let mut extent = D::zero(cx); match self.0.as_ref() { Node::Internal { summary, .. } | Node::Leaf { summary, .. } => { extent.add_summary(summary, cx); } } extent } pub fn summary(&self) -> &T::Summary { match self.0.as_ref() { Node::Internal { summary, .. } => summary, Node::Leaf { summary, .. } => summary, } } pub fn is_empty(&self) -> bool { match self.0.as_ref() { Node::Internal { .. } => false, Node::Leaf { items, .. } => items.is_empty(), } } pub fn extend(&mut self, iter: I, cx: ::Context<'_>) where I: IntoIterator, { self.append(Self::from_iter(iter, cx), cx); } pub fn par_extend(&mut self, iter: I, cx: ::Context<'_>) where I: IntoParallelIterator, Iter: IndexedParallelIterator, T: Send + Sync, T::Summary: Send + Sync, for<'a> ::Context<'a>: Sync, { self.append(Self::from_par_iter(iter, cx), cx); } pub fn push(&mut self, item: T, cx: ::Context<'_>) { let summary = item.summary(cx); self.append( SumTree(Arc::new(Node::Leaf { summary: summary.clone(), items: ArrayVec::from_iter(Some(item)), item_summaries: ArrayVec::from_iter(Some(summary)), })), cx, ); } pub fn append(&mut self, mut other: Self, cx: ::Context<'_>) { if self.is_empty() { *self = other; } else if !other.0.is_leaf() || !other.0.items().is_empty() { if self.0.height() < other.0.height() { if let Some(tree) = Self::append_large(self.clone(), &mut other, cx) { *self = Self::from_child_trees(tree, other, cx); } else { *self = other; } } else if let Some(split_tree) = self.push_tree_recursive(other, cx) { *self = Self::from_child_trees(self.clone(), split_tree, cx); } } } fn push_tree_recursive( &mut self, other: SumTree, cx: ::Context<'_>, ) -> Option> { match Arc::make_mut(&mut self.0) { Node::Internal { height, summary, child_summaries, child_trees, .. } => { let other_node = other.0.clone(); ::add_summary(summary, other_node.summary(), cx); let height_delta = *height - other_node.height(); let mut summaries_to_append = ArrayVec::::new(); let mut trees_to_append = ArrayVec::, { 2 * TREE_BASE }, u8>::new(); if height_delta == 0 { summaries_to_append.extend(other_node.child_summaries().iter().cloned()); trees_to_append.extend(other_node.child_trees().iter().cloned()); } else if height_delta == 1 && !other_node.is_underflowing() { summaries_to_append .push(other_node.summary().clone()) .unwrap_oob(); trees_to_append.push(other).unwrap_oob(); } else { let tree_to_append = child_trees .last_mut() .unwrap() .push_tree_recursive(other, cx); *child_summaries.last_mut().unwrap() = child_trees.last().unwrap().0.summary().clone(); if let Some(split_tree) = tree_to_append { summaries_to_append .push(split_tree.0.summary().clone()) .unwrap_oob(); trees_to_append.push(split_tree).unwrap_oob(); } } let child_count = child_trees.len() + trees_to_append.len(); if child_count > 2 * TREE_BASE { let left_summaries: ArrayVec<_, { 2 * TREE_BASE }, u8>; let right_summaries: ArrayVec<_, { 2 * TREE_BASE }, u8>; let left_trees; let right_trees; let midpoint = (child_count + child_count % 2) / 2; { let mut all_summaries = child_summaries .iter() .chain(summaries_to_append.iter()) .cloned(); left_summaries = all_summaries.by_ref().take(midpoint).collect(); right_summaries = all_summaries.collect(); let mut all_trees = child_trees.iter().chain(trees_to_append.iter()).cloned(); left_trees = all_trees.by_ref().take(midpoint).collect(); right_trees = all_trees.collect(); } *summary = sum(left_summaries.iter(), cx); *child_summaries = left_summaries; *child_trees = left_trees; Some(SumTree(Arc::new(Node::Internal { height: *height, summary: sum(right_summaries.iter(), cx), child_summaries: right_summaries, child_trees: right_trees, }))) } else { child_summaries.extend(summaries_to_append); child_trees.extend(trees_to_append); None } } Node::Leaf { summary, items, item_summaries, } => { let other_node = other.0; let child_count = items.len() + other_node.items().len(); if child_count > 2 * TREE_BASE { let left_items; let right_items; let left_summaries; let right_summaries: ArrayVec; let midpoint = (child_count + child_count % 2) / 2; { let mut all_items = items.iter().chain(other_node.items().iter()).cloned(); left_items = all_items.by_ref().take(midpoint).collect(); right_items = all_items.collect(); let mut all_summaries = item_summaries .iter() .chain(other_node.child_summaries()) .cloned(); left_summaries = all_summaries.by_ref().take(midpoint).collect(); right_summaries = all_summaries.collect(); } *items = left_items; *item_summaries = left_summaries; *summary = sum(item_summaries.iter(), cx); Some(SumTree(Arc::new(Node::Leaf { items: right_items, summary: sum(right_summaries.iter(), cx), item_summaries: right_summaries, }))) } else { ::add_summary(summary, other_node.summary(), cx); items.extend(other_node.items().iter().cloned()); item_summaries.extend(other_node.child_summaries().iter().cloned()); None } } } } // appends the `large` tree to a `small` tree, assumes small.height() <= large.height() fn append_large( small: Self, large: &mut Self, cx: ::Context<'_>, ) -> Option { if small.0.height() == large.0.height() { if !small.0.is_underflowing() { Some(small) } else { Self::merge_into_right(small, large, cx) } } else { debug_assert!(small.0.height() < large.0.height()); let Node::Internal { height, summary, child_summaries, child_trees, } = Arc::make_mut(&mut large.0) else { unreachable!(); }; let mut full_summary = small.summary().clone(); Summary::add_summary(&mut full_summary, summary, cx); *summary = full_summary; let first = child_trees.first_mut().unwrap(); let res = Self::append_large(small, first, cx); *child_summaries.first_mut().unwrap() = first.summary().clone(); if let Some(tree) = res { if child_trees.len() < 2 * TREE_BASE { child_summaries .insert(0, tree.summary().clone()) .unwrap_oob(); child_trees.insert(0, tree).unwrap_oob(); None } else { let new_child_summaries = { let mut res = ArrayVec::from_iter([tree.summary().clone()]); res.extend(child_summaries.drain(..TREE_BASE)); res }; let tree = SumTree(Arc::new(Node::Internal { height: *height, summary: sum(new_child_summaries.iter(), cx), child_summaries: new_child_summaries, child_trees: { let mut res = ArrayVec::from_iter([tree]); res.extend(child_trees.drain(..TREE_BASE)); res }, })); *summary = sum(child_summaries.iter(), cx); Some(tree) } } else { None } } } // Merge two nodes into `large`. // // `large` will contain the contents of `small` followed by its own data. // If the combined data exceed the node capacity, returns a new node that // holds the first half of the merged items and `large` is left with the // second half // // The nodes must be on the same height // It only makes sense to call this when `small` is underflowing fn merge_into_right( small: Self, large: &mut Self, cx: <::Summary as Summary>::Context<'_>, ) -> Option> { debug_assert_eq!(small.0.height(), large.0.height()); match (small.0.as_ref(), Arc::make_mut(&mut large.0)) { ( Node::Internal { summary: small_summary, child_summaries: small_child_summaries, child_trees: small_child_trees, .. }, Node::Internal { summary, child_summaries, child_trees, height, }, ) => { let total_child_count = child_trees.len() + small_child_trees.len(); if total_child_count <= 2 * TREE_BASE { let mut all_trees = small_child_trees.clone(); all_trees.extend(child_trees.drain(..)); *child_trees = all_trees; let mut all_summaries = small_child_summaries.clone(); all_summaries.extend(child_summaries.drain(..)); *child_summaries = all_summaries; let mut full_summary = small_summary.clone(); Summary::add_summary(&mut full_summary, summary, cx); *summary = full_summary; None } else { let midpoint = total_child_count.div_ceil(2); let mut all_trees = small_child_trees.iter().chain(child_trees.iter()).cloned(); let left_trees = all_trees.by_ref().take(midpoint).collect(); *child_trees = all_trees.collect(); let mut all_summaries = small_child_summaries .iter() .chain(child_summaries.iter()) .cloned(); let left_summaries: ArrayVec<_, { 2 * TREE_BASE }, u8> = all_summaries.by_ref().take(midpoint).collect(); *child_summaries = all_summaries.collect(); *summary = sum(child_summaries.iter(), cx); Some(SumTree(Arc::new(Node::Internal { height: *height, summary: sum(left_summaries.iter(), cx), child_summaries: left_summaries, child_trees: left_trees, }))) } } ( Node::Leaf { summary: small_summary, items: small_items, item_summaries: small_item_summaries, }, Node::Leaf { summary, items, item_summaries, }, ) => { let total_child_count = small_items.len() + items.len(); if total_child_count <= 2 * TREE_BASE { let mut all_items = small_items.clone(); all_items.extend(items.drain(..)); *items = all_items; let mut all_summaries = small_item_summaries.clone(); all_summaries.extend(item_summaries.drain(..)); *item_summaries = all_summaries; let mut full_summary = small_summary.clone(); Summary::add_summary(&mut full_summary, summary, cx); *summary = full_summary; None } else { let midpoint = total_child_count.div_ceil(2); let mut all_items = small_items.iter().chain(items.iter()).cloned(); let left_items = all_items.by_ref().take(midpoint).collect(); *items = all_items.collect(); let mut all_summaries = small_item_summaries .iter() .chain(item_summaries.iter()) .cloned(); let left_summaries: ArrayVec<_, { 2 * TREE_BASE }, u8> = all_summaries.by_ref().take(midpoint).collect(); *item_summaries = all_summaries.collect(); *summary = sum(item_summaries.iter(), cx); Some(SumTree(Arc::new(Node::Leaf { items: left_items, summary: sum(left_summaries.iter(), cx), item_summaries: left_summaries, }))) } } _ => unreachable!(), } } fn from_child_trees( left: SumTree, right: SumTree, cx: ::Context<'_>, ) -> Self { let height = left.0.height() + 1; let mut child_summaries = ArrayVec::new(); child_summaries.push(left.0.summary().clone()).unwrap_oob(); child_summaries.push(right.0.summary().clone()).unwrap_oob(); let mut child_trees = ArrayVec::new(); child_trees.push(left).unwrap_oob(); child_trees.push(right).unwrap_oob(); SumTree(Arc::new(Node::Internal { height, summary: sum(child_summaries.iter(), cx), child_summaries, child_trees, })) } fn leftmost_leaf(&self) -> &Self { match *self.0 { Node::Leaf { .. } => self, Node::Internal { ref child_trees, .. } => child_trees.first().unwrap().leftmost_leaf(), } } fn rightmost_leaf(&self) -> &Self { match *self.0 { Node::Leaf { .. } => self, Node::Internal { ref child_trees, .. } => child_trees.last().unwrap().rightmost_leaf(), } } } impl PartialEq for SumTree { fn eq(&self, other: &Self) -> bool { self.iter().eq(other.iter()) } } impl Eq for SumTree {} impl SumTree { pub fn insert_or_replace<'a, 'b>( &'a mut self, item: T, cx: ::Context<'b>, ) -> Option { let mut replaced = None; { let mut cursor = self.cursor::(cx); let mut new_tree = cursor.slice(&item.key(), Bias::Left); if let Some(cursor_item) = cursor.item() && cursor_item.key() == item.key() { replaced = Some(cursor_item.clone()); cursor.next(); } new_tree.push(item, cx); new_tree.append(cursor.suffix(), cx); drop(cursor); *self = new_tree }; replaced } pub fn remove(&mut self, key: &T::Key, cx: ::Context<'_>) -> Option { let mut removed = None; *self = { let mut cursor = self.cursor::(cx); let mut new_tree = cursor.slice(key, Bias::Left); if let Some(item) = cursor.item() && item.key() == *key { removed = Some(item.clone()); cursor.next(); } new_tree.append(cursor.suffix(), cx); new_tree }; removed } pub fn edit( &mut self, mut edits: Vec>, cx: ::Context<'_>, ) -> Vec { if edits.is_empty() { return Vec::new(); } let mut removed = Vec::new(); edits.sort_unstable_by_key(|item| item.key()); *self = { let mut cursor = self.cursor::(cx); let mut new_tree = SumTree::new(cx); let mut buffered_items = Vec::new(); cursor.seek(&T::Key::zero(cx), Bias::Left); for edit in edits { let new_key = edit.key(); let mut old_item = cursor.item(); if old_item .as_ref() .is_some_and(|old_item| old_item.key() < new_key) { new_tree.extend(buffered_items.drain(..), cx); let slice = cursor.slice(&new_key, Bias::Left); new_tree.append(slice, cx); old_item = cursor.item(); } if let Some(old_item) = old_item && old_item.key() == new_key { removed.push(old_item.clone()); cursor.next(); } match edit { Edit::Insert(item) => { buffered_items.push(item); } Edit::Remove(_) => {} } } new_tree.extend(buffered_items, cx); new_tree.append(cursor.suffix(), cx); new_tree }; removed } pub fn get<'a>( &'a self, key: &T::Key, cx: ::Context<'a>, ) -> Option<&'a T> { if let (_, _, Some(item)) = self.find_exact::(cx, key, Bias::Left) { Some(item) } else { None } } } impl Default for SumTree where T: Item
, S: for<'a> Summary = ()>, { fn default() -> Self { Self::new(()) } } #[derive(Clone)] pub enum Node { Internal { height: u8, summary: T::Summary, child_summaries: ArrayVec, child_trees: ArrayVec, { 2 * TREE_BASE }, u8>, }, Leaf { summary: T::Summary, items: ArrayVec, item_summaries: ArrayVec, }, } impl fmt::Debug for Node where T: Item + fmt::Debug, T::Summary: fmt::Debug, { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { match self { Node::Internal { height, summary, child_summaries, child_trees, } => f .debug_struct("Internal") .field("height", height) .field("summary", summary) .field("child_summaries", child_summaries) .field("child_trees", child_trees) .finish(), Node::Leaf { summary, items, item_summaries, } => f .debug_struct("Leaf") .field("summary", summary) .field("items", items) .field("item_summaries", item_summaries) .finish(), } } } impl Node { fn is_leaf(&self) -> bool { matches!(self, Node::Leaf { .. }) } fn height(&self) -> u8 { match self { Node::Internal { height, .. } => *height, Node::Leaf { .. } => 0, } } fn summary(&self) -> &T::Summary { match self { Node::Internal { summary, .. } => summary, Node::Leaf { summary, .. } => summary, } } fn child_summaries(&self) -> &[T::Summary] { match self { Node::Internal { child_summaries, .. } => child_summaries.as_slice(), Node::Leaf { item_summaries, .. } => item_summaries.as_slice(), } } fn child_trees(&self) -> &ArrayVec, { 2 * TREE_BASE }, u8> { match self { Node::Internal { child_trees, .. } => child_trees, Node::Leaf { .. } => panic!("Leaf nodes have no child trees"), } } fn items(&self) -> &ArrayVec { match self { Node::Leaf { items, .. } => items, Node::Internal { .. } => panic!("Internal nodes have no items"), } } fn is_underflowing(&self) -> bool { match self { Node::Internal { child_trees, .. } => child_trees.len() < TREE_BASE, Node::Leaf { items, .. } => items.len() < TREE_BASE, } } } #[derive(Debug)] pub enum Edit { Insert(T), Remove(T::Key), } impl Edit { fn key(&self) -> T::Key { match self { Edit::Insert(item) => item.key(), Edit::Remove(key) => key.clone(), } } } fn sum<'a, T, I>(iter: I, cx: T::Context<'_>) -> T where T: 'a + Summary, I: Iterator, { let mut sum = T::zero(cx); for value in iter { sum.add_summary(value, cx); } sum } #[cfg(test)] mod tests { use super::*; use rand::{distr::StandardUniform, prelude::*}; use std::cmp; #[ctor::ctor] fn init_logger() { zlog::init_test(); } #[test] fn test_extend_and_push_tree() { let mut tree1 = SumTree::default(); tree1.extend(0..20, ()); let mut tree2 = SumTree::default(); tree2.extend(50..100, ()); tree1.append(tree2, ()); assert_eq!(tree1.items(()), (0..20).chain(50..100).collect::>()); } #[test] fn test_random() { let mut starting_seed = 0; if let Ok(value) = std::env::var("SEED") { starting_seed = value.parse().expect("invalid SEED variable"); } let mut num_iterations = 100; if let Ok(value) = std::env::var("ITERATIONS") { num_iterations = value.parse().expect("invalid ITERATIONS variable"); } let num_operations = std::env::var("OPERATIONS") .map_or(5, |o| o.parse().expect("invalid OPERATIONS variable")); for seed in starting_seed..(starting_seed + num_iterations) { eprintln!("seed = {}", seed); let mut rng = StdRng::seed_from_u64(seed); let rng = &mut rng; let mut tree = SumTree::::default(); let count = rng.random_range(0..10); if rng.random() { tree.extend(rng.sample_iter(StandardUniform).take(count), ()); } else { let items = rng .sample_iter(StandardUniform) .take(count) .collect::>(); tree.par_extend(items, ()); } for _ in 0..num_operations { let splice_end = rng.random_range(0..tree.extent::(()).0 + 1); let splice_start = rng.random_range(0..splice_end + 1); let count = rng.random_range(0..10); let tree_end = tree.extent::(()); let new_items = rng .sample_iter(StandardUniform) .take(count) .collect::>(); let mut reference_items = tree.items(()); reference_items.splice(splice_start..splice_end, new_items.clone()); tree = { let mut cursor = tree.cursor::(()); let mut new_tree = cursor.slice(&Count(splice_start), Bias::Right); if rng.random() { new_tree.extend(new_items, ()); } else { new_tree.par_extend(new_items, ()); } cursor.seek(&Count(splice_end), Bias::Right); new_tree.append(cursor.slice(&tree_end, Bias::Right), ()); new_tree }; assert_eq!(tree.items(()), reference_items); assert_eq!( tree.iter().collect::>(), tree.cursor::<()>(()).collect::>() ); log::info!("tree items: {:?}", tree.items(())); let mut filter_cursor = tree.filter::<_, Count>((), |summary| summary.contains_even); let expected_filtered_items = tree .items(()) .into_iter() .enumerate() .filter(|(_, item)| (item & 1) == 0) .collect::>(); let mut item_ix = if rng.random() { filter_cursor.next(); 0 } else { filter_cursor.prev(); expected_filtered_items.len().saturating_sub(1) }; while item_ix < expected_filtered_items.len() { log::info!("filter_cursor, item_ix: {}", item_ix); let actual_item = filter_cursor.item().unwrap(); let (reference_index, reference_item) = expected_filtered_items[item_ix]; assert_eq!(actual_item, &reference_item); assert_eq!(filter_cursor.start().0, reference_index); log::info!("next"); filter_cursor.next(); item_ix += 1; while item_ix > 0 && rng.random_bool(0.2) { log::info!("prev"); filter_cursor.prev(); item_ix -= 1; if item_ix == 0 && rng.random_bool(0.2) { filter_cursor.prev(); assert_eq!(filter_cursor.item(), None); assert_eq!(filter_cursor.start().0, 0); filter_cursor.next(); } } } assert_eq!(filter_cursor.item(), None); let mut before_start = false; let mut cursor = tree.cursor::(()); let start_pos = rng.random_range(0..=reference_items.len()); cursor.seek(&Count(start_pos), Bias::Right); let mut pos = rng.random_range(start_pos..=reference_items.len()); cursor.seek_forward(&Count(pos), Bias::Right); for i in 0..10 { assert_eq!(cursor.start().0, pos); if pos > 0 { assert_eq!(cursor.prev_item().unwrap(), &reference_items[pos - 1]); } else { assert_eq!(cursor.prev_item(), None); } if pos < reference_items.len() && !before_start { assert_eq!(cursor.item().unwrap(), &reference_items[pos]); } else { assert_eq!(cursor.item(), None); } if before_start { assert_eq!(cursor.next_item(), reference_items.first()); } else if pos + 1 < reference_items.len() { assert_eq!(cursor.next_item().unwrap(), &reference_items[pos + 1]); } else { assert_eq!(cursor.next_item(), None); } if i < 5 { cursor.next(); if pos < reference_items.len() { pos += 1; before_start = false; } } else { cursor.prev(); if pos == 0 { before_start = true; } pos = pos.saturating_sub(1); } } } for _ in 0..10 { let end = rng.random_range(0..tree.extent::(()).0 + 1); let start = rng.random_range(0..end + 1); let start_bias = if rng.random() { Bias::Left } else { Bias::Right }; let end_bias = if rng.random() { Bias::Left } else { Bias::Right }; let mut cursor = tree.cursor::(()); cursor.seek(&Count(start), start_bias); let slice = cursor.slice(&Count(end), end_bias); cursor.seek(&Count(start), start_bias); let summary = cursor.summary::<_, Sum>(&Count(end), end_bias); assert_eq!(summary.0, slice.summary().sum); } } } #[test] fn test_cursor() { // Empty tree let tree = SumTree::::default(); let mut cursor = tree.cursor::(()); assert_eq!( cursor.slice(&Count(0), Bias::Right).items(()), Vec::::new() ); assert_eq!(cursor.item(), None); assert_eq!(cursor.prev_item(), None); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 0); cursor.prev(); assert_eq!(cursor.item(), None); assert_eq!(cursor.prev_item(), None); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 0); cursor.next(); assert_eq!(cursor.item(), None); assert_eq!(cursor.prev_item(), None); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 0); // Single-element tree let mut tree = SumTree::::default(); tree.extend(vec![1], ()); let mut cursor = tree.cursor::(()); assert_eq!( cursor.slice(&Count(0), Bias::Right).items(()), Vec::::new() ); assert_eq!(cursor.item(), Some(&1)); assert_eq!(cursor.prev_item(), None); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 0); cursor.next(); assert_eq!(cursor.item(), None); assert_eq!(cursor.prev_item(), Some(&1)); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 1); cursor.prev(); assert_eq!(cursor.item(), Some(&1)); assert_eq!(cursor.prev_item(), None); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 0); let mut cursor = tree.cursor::(()); assert_eq!(cursor.slice(&Count(1), Bias::Right).items(()), [1]); assert_eq!(cursor.item(), None); assert_eq!(cursor.prev_item(), Some(&1)); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 1); cursor.seek(&Count(0), Bias::Right); assert_eq!( cursor .slice(&tree.extent::(()), Bias::Right) .items(()), [1] ); assert_eq!(cursor.item(), None); assert_eq!(cursor.prev_item(), Some(&1)); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 1); // Multiple-element tree let mut tree = SumTree::default(); tree.extend(vec![1, 2, 3, 4, 5, 6], ()); let mut cursor = tree.cursor::(()); assert_eq!(cursor.slice(&Count(2), Bias::Right).items(()), [1, 2]); assert_eq!(cursor.item(), Some(&3)); assert_eq!(cursor.prev_item(), Some(&2)); assert_eq!(cursor.next_item(), Some(&4)); assert_eq!(cursor.start().sum, 3); cursor.next(); assert_eq!(cursor.item(), Some(&4)); assert_eq!(cursor.prev_item(), Some(&3)); assert_eq!(cursor.next_item(), Some(&5)); assert_eq!(cursor.start().sum, 6); cursor.next(); assert_eq!(cursor.item(), Some(&5)); assert_eq!(cursor.prev_item(), Some(&4)); assert_eq!(cursor.next_item(), Some(&6)); assert_eq!(cursor.start().sum, 10); cursor.next(); assert_eq!(cursor.item(), Some(&6)); assert_eq!(cursor.prev_item(), Some(&5)); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 15); cursor.next(); cursor.next(); assert_eq!(cursor.item(), None); assert_eq!(cursor.prev_item(), Some(&6)); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 21); cursor.prev(); assert_eq!(cursor.item(), Some(&6)); assert_eq!(cursor.prev_item(), Some(&5)); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 15); cursor.prev(); assert_eq!(cursor.item(), Some(&5)); assert_eq!(cursor.prev_item(), Some(&4)); assert_eq!(cursor.next_item(), Some(&6)); assert_eq!(cursor.start().sum, 10); cursor.prev(); assert_eq!(cursor.item(), Some(&4)); assert_eq!(cursor.prev_item(), Some(&3)); assert_eq!(cursor.next_item(), Some(&5)); assert_eq!(cursor.start().sum, 6); cursor.prev(); assert_eq!(cursor.item(), Some(&3)); assert_eq!(cursor.prev_item(), Some(&2)); assert_eq!(cursor.next_item(), Some(&4)); assert_eq!(cursor.start().sum, 3); cursor.prev(); assert_eq!(cursor.item(), Some(&2)); assert_eq!(cursor.prev_item(), Some(&1)); assert_eq!(cursor.next_item(), Some(&3)); assert_eq!(cursor.start().sum, 1); cursor.prev(); assert_eq!(cursor.item(), Some(&1)); assert_eq!(cursor.prev_item(), None); assert_eq!(cursor.next_item(), Some(&2)); assert_eq!(cursor.start().sum, 0); cursor.prev(); assert_eq!(cursor.item(), None); assert_eq!(cursor.prev_item(), None); assert_eq!(cursor.next_item(), Some(&1)); assert_eq!(cursor.start().sum, 0); cursor.next(); assert_eq!(cursor.item(), Some(&1)); assert_eq!(cursor.prev_item(), None); assert_eq!(cursor.next_item(), Some(&2)); assert_eq!(cursor.start().sum, 0); let mut cursor = tree.cursor::(()); assert_eq!( cursor .slice(&tree.extent::(()), Bias::Right) .items(()), tree.items(()) ); assert_eq!(cursor.item(), None); assert_eq!(cursor.prev_item(), Some(&6)); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 21); cursor.seek(&Count(3), Bias::Right); assert_eq!( cursor .slice(&tree.extent::(()), Bias::Right) .items(()), [4, 5, 6] ); assert_eq!(cursor.item(), None); assert_eq!(cursor.prev_item(), Some(&6)); assert_eq!(cursor.next_item(), None); assert_eq!(cursor.start().sum, 21); // Seeking can bias left or right cursor.seek(&Count(1), Bias::Left); assert_eq!(cursor.item(), Some(&1)); cursor.seek(&Count(1), Bias::Right); assert_eq!(cursor.item(), Some(&2)); // Slicing without resetting starts from where the cursor is parked at. cursor.seek(&Count(1), Bias::Right); assert_eq!(cursor.slice(&Count(3), Bias::Right).items(()), vec![2, 3]); assert_eq!(cursor.slice(&Count(6), Bias::Left).items(()), vec![4, 5]); assert_eq!(cursor.slice(&Count(6), Bias::Right).items(()), vec![6]); } #[test] fn test_edit() { let mut tree = SumTree::::default(); let removed = tree.edit(vec![Edit::Insert(1), Edit::Insert(2), Edit::Insert(0)], ()); assert_eq!(tree.items(()), vec![0, 1, 2]); assert_eq!(removed, Vec::::new()); assert_eq!(tree.get(&0, ()), Some(&0)); assert_eq!(tree.get(&1, ()), Some(&1)); assert_eq!(tree.get(&2, ()), Some(&2)); assert_eq!(tree.get(&4, ()), None); let removed = tree.edit(vec![Edit::Insert(2), Edit::Insert(4), Edit::Remove(0)], ()); assert_eq!(tree.items(()), vec![1, 2, 4]); assert_eq!(removed, vec![0, 2]); assert_eq!(tree.get(&0, ()), None); assert_eq!(tree.get(&1, ()), Some(&1)); assert_eq!(tree.get(&2, ()), Some(&2)); assert_eq!(tree.get(&4, ()), Some(&4)); } #[test] fn test_from_iter() { assert_eq!( SumTree::from_iter(0..100, ()).items(()), (0..100).collect::>() ); // Ensure `from_iter` works correctly when the given iterator restarts // after calling `next` if `None` was already returned. let mut ix = 0; let iterator = std::iter::from_fn(|| { ix = (ix + 1) % 2; if ix == 1 { Some(1) } else { None } }); assert_eq!(SumTree::from_iter(iterator, ()).items(()), vec![1]); } #[derive(Clone, Default, Debug)] pub struct IntegersSummary { count: usize, sum: usize, contains_even: bool, max: u8, } #[derive(Ord, PartialOrd, Default, Eq, PartialEq, Clone, Debug)] struct Count(usize); #[derive(Ord, PartialOrd, Default, Eq, PartialEq, Clone, Debug)] struct Sum(usize); impl Item for u8 { type Summary = IntegersSummary; fn summary(&self, _cx: ()) -> Self::Summary { IntegersSummary { count: 1, sum: *self as usize, contains_even: (*self & 1) == 0, max: *self, } } } impl KeyedItem for u8 { type Key = u8; fn key(&self) -> Self::Key { *self } } impl ContextLessSummary for IntegersSummary { fn zero() -> Self { Default::default() } fn add_summary(&mut self, other: &Self) { self.count += other.count; self.sum += other.sum; self.contains_even |= other.contains_even; self.max = cmp::max(self.max, other.max); } } impl Dimension<'_, IntegersSummary> for u8 { fn zero(_cx: ()) -> Self { Default::default() } fn add_summary(&mut self, summary: &IntegersSummary, _: ()) { *self = summary.max; } } impl Dimension<'_, IntegersSummary> for Count { fn zero(_cx: ()) -> Self { Default::default() } fn add_summary(&mut self, summary: &IntegersSummary, _: ()) { self.0 += summary.count; } } impl SeekTarget<'_, IntegersSummary, IntegersSummary> for Count { fn cmp(&self, cursor_location: &IntegersSummary, _: ()) -> Ordering { self.0.cmp(&cursor_location.count) } } impl Dimension<'_, IntegersSummary> for Sum { fn zero(_cx: ()) -> Self { Default::default() } fn add_summary(&mut self, summary: &IntegersSummary, _: ()) { self.0 += summary.sum; } } }