//! Implementation of [Ordered] that uses an ordered map internally to map translated keys to //! arbitrary values. Beyond the standard [Unordered] implementation, this variant adds the //! capability to retrieve values associated with both next and previous translated keys of a given //! key. There is no ordering guarantee provided over the values associated with each key. Ordering //! applies only to the _translated_ key space. use crate::{ index::{ storage::{insert_front, Cursor as CursorImpl, ImmutableCursor, IndexEntry, Record}, Cursor as CursorTrait, Ordered, Unordered, }, translator::Translator, }; use commonware_runtime::{ telemetry::metrics::{Counter, Gauge, MetricsExt as _}, Metrics, }; use std::{ collections::{ btree_map::{ Entry as BTreeEntry, OccupiedEntry as BTreeOccupiedEntry, VacantEntry as BTreeVacantEntry, }, BTreeMap, }, ops::Bound::{Excluded, Unbounded}, }; /// Implementation of [IndexEntry] for [BTreeOccupiedEntry]. impl IndexEntry for BTreeOccupiedEntry<'_, K, Record> { fn get_mut(&mut self) -> &mut Record { self.get_mut() } fn remove(self) { self.remove_entry(); } } /// A [crate::index::Cursor] over the values associated with a translated key. pub type Cursor<'a, K, V> = CursorImpl<'a, V, BTreeOccupiedEntry<'a, K, Record>>; /// A memory-efficient index that uses an ordered map internally to map translated keys to arbitrary /// values. pub struct Index { translator: T, map: BTreeMap>, keys: Gauge, items: Gauge, pruned: Counter, } impl Index { /// Create a new entry in the index. fn create(keys: &Gauge, items: &Gauge, vacant: BTreeVacantEntry<'_, T::Key, Record>, v: V) { keys.inc(); items.inc(); vacant.insert(Record { value: v, next: None, }); } /// Create a new [Index] with the given translator and metrics registry. pub fn new(ctx: impl Metrics, translator: T) -> Self { Self { translator, map: BTreeMap::new(), keys: ctx.gauge("keys", "Number of translated keys in the index"), items: ctx.gauge("items", "Number of items in the index"), pruned: ctx.counter("pruned", "Number of items pruned"), } } /// Like [Ordered::next_translated_key] but without cycling around to the first key if there is /// no next key. pub(super) fn next_translated_key_no_cycle<'a>( &'a self, key: &[u8], ) -> Option> { let k = self.translator.transform(key); self.map .range((Excluded(k), Unbounded)) .next() .map(|(_, record)| ImmutableCursor::new(record)) } /// Like [Ordered::prev_translated_key] but without cycling around to the last key if there is /// no previous key. pub(super) fn prev_translated_key_no_cycle<'a>( &'a self, key: &[u8], ) -> Option> { let k = self.translator.transform(key); self.map .range(..k) .next_back() .map(|(_, record)| ImmutableCursor::new(record)) } } impl Ordered for Index { type Iterator<'a> = ImmutableCursor<'a, V> where Self: 'a; fn prev_translated_key<'a>(&'a self, key: &[u8]) -> Option<(Self::Iterator<'a>, bool)> where Self::Value: 'a, { let res = self.prev_translated_key_no_cycle(key); if let Some(res) = res { return Some((res, false)); } self.last_translated_key().map(|res| (res, true)) } fn next_translated_key<'a>(&'a self, key: &[u8]) -> Option<(Self::Iterator<'a>, bool)> where Self::Value: 'a, { let res = self.next_translated_key_no_cycle(key); if let Some(res) = res { return Some((res, false)); } self.first_translated_key().map(|res| (res, true)) } fn first_translated_key<'a>(&'a self) -> Option> where Self::Value: 'a, { self.map .first_key_value() .map(|(_, record)| ImmutableCursor::new(record)) } fn last_translated_key<'a>(&'a self) -> Option> where Self::Value: 'a, { self.map .last_key_value() .map(|(_, record)| ImmutableCursor::new(record)) } } impl super::Factory for Index { fn new(ctx: impl commonware_runtime::Metrics, translator: T) -> Self { Self::new(ctx, translator) } } impl Unordered for Index { type Value = V; type Cursor<'a> = Cursor<'a, T::Key, V> where Self: 'a; fn get<'a>(&'a self, key: &[u8]) -> impl Iterator + 'a where V: 'a, { let k = self.translator.transform(key); self.map .get(&k) .map(|record| ImmutableCursor::new(record)) .into_iter() .flatten() } fn get_mut<'a>(&'a mut self, key: &[u8]) -> Option> { let k = self.translator.transform(key); match self.map.entry(k) { BTreeEntry::Occupied(entry) => Some(Cursor::<'_, T::Key, V>::new( entry, &self.keys, &self.items, &self.pruned, )), BTreeEntry::Vacant(_) => None, } } fn get_mut_or_insert<'a>(&'a mut self, key: &[u8], value: V) -> Option> { let k = self.translator.transform(key); match self.map.entry(k) { BTreeEntry::Occupied(entry) => Some(Cursor::<'_, T::Key, V>::new( entry, &self.keys, &self.items, &self.pruned, )), BTreeEntry::Vacant(entry) => { Self::create(&self.keys, &self.items, entry, value); None } } } fn insert(&mut self, key: &[u8], value: V) { let k = self.translator.transform(key); match self.map.entry(k) { BTreeEntry::Occupied(mut entry) => { insert_front(entry.get_mut(), value); self.items.inc(); } BTreeEntry::Vacant(entry) => { Self::create(&self.keys, &self.items, entry, value); } } } fn insert_and_retain(&mut self, key: &[u8], value: V, should_retain: impl Fn(&V) -> bool) { let k = self.translator.transform(key); match self.map.entry(k) { BTreeEntry::Occupied(entry) => { let mut cursor = Cursor::<'_, T::Key, V>::new(entry, &self.keys, &self.items, &self.pruned); // Drop anything that should not be retained. cursor.retain(&should_retain); // Add the new value only if it should be retained. if should_retain(&value) { cursor.insert(value); } } BTreeEntry::Vacant(entry) => { // Create the entry only if the value should be retained. if should_retain(&value) { Self::create(&self.keys, &self.items, entry, value); } } } } fn remove(&mut self, key: &[u8]) { let k = self.translator.transform(key); if let Some(mut record) = self.map.remove(&k) { // To ensure metrics are accurate, account for all conflicting values in the chain. self.keys.dec(); self.items.dec(); self.pruned.inc(); while let Some(next) = record.next.take() { self.items.dec(); self.pruned.inc(); record = *next; } } } #[cfg(test)] fn keys(&self) -> usize { self.map.len() } #[cfg(test)] fn items(&self) -> usize { self.items.get() as usize } #[cfg(test)] fn pruned(&self) -> usize { self.pruned.get() as usize } } impl Drop for Index { /// To avoid stack overflow on keys with many collisions, we implement an iterative drop (in /// lieu of Rust's default recursive drop). fn drop(&mut self) { for (_, record) in self.map.iter_mut() { let mut next = record.next.take(); while let Some(mut record) = next { next = record.next.take(); } } } } #[cfg(test)] mod tests { use super::*; use crate::translator::OneCap; use commonware_formatting::hex; use commonware_macros::test_traced; use commonware_runtime::{deterministic, Runner}; #[test_traced] fn test_ordered_empty_index() { let runner = deterministic::Runner::default(); runner.start(|context| async move { let index = Index::<_, u64>::new(context, OneCap); assert!(index.first_translated_key().is_none()); assert!(index.last_translated_key().is_none()); assert!(index.prev_translated_key(b"key").is_none()); assert!(index.next_translated_key(b"key").is_none()); }); } #[test_traced] fn test_ordered_index_ordering() { let runner = deterministic::Runner::default(); runner.start(|context| async move { let mut index = Index::<_, u64>::new(context, OneCap); assert_eq!(index.keys(), 0); let k1 = &hex!("0x0b02AA"); // translated key 0b let k2 = &hex!("0x1c04CC"); // translated key 1c let k2_collides = &hex!("0x1c0311"); let k3 = &hex!("0x2d06EE"); // translated key 2d index.insert(k1, 1); index.insert(k2, 21); index.insert(k2_collides, 22); index.insert(k3, 3); assert_eq!(index.keys(), 3); // First translated key is 0b. let mut next = index.first_translated_key().unwrap(); assert_eq!(next.next().unwrap(), &1); assert_eq!(next.next(), None); // Next translated key to 0x00 is 0b. let (mut next, wrapped) = index.next_translated_key(&[0x00]).unwrap(); assert!(!wrapped); assert_eq!(next.next().unwrap(), &1); assert_eq!(next.next(), None); // Next translated key to 0x0b is 1c. let (mut next, wrapped) = index.next_translated_key(&hex!("0x0b0102")).unwrap(); assert!(!wrapped); assert_eq!(next.next().unwrap(), &22); assert_eq!(next.next().unwrap(), &21); assert_eq!(next.next(), None); // Next translated key to 0x1b is 1c. let (mut next, wrapped) = index.next_translated_key(&hex!("0x1b010203")).unwrap(); assert!(!wrapped); assert_eq!(next.next().unwrap(), &22); assert_eq!(next.next().unwrap(), &21); assert_eq!(next.next(), None); // Next translated key to 0x2a is 2d. let (mut next, wrapped) = index.next_translated_key(&hex!("0x2a01020304")).unwrap(); assert!(!wrapped); assert_eq!(next.next().unwrap(), &3); assert_eq!(next.next(), None); // Next translated key to 0x2d cycles around to 0x0b. let (mut next, wrapped) = index.next_translated_key(k3).unwrap(); assert!(wrapped); assert_eq!(next.next().unwrap(), &1); assert_eq!(next.next(), None); // Another cycle-around case. let (mut next, wrapped) = index.next_translated_key(&hex!("0x2eFF")).unwrap(); assert!(wrapped); assert_eq!(next.next().unwrap(), &1); assert_eq!(next.next(), None); // Previous translated key of first key is the last key. let (mut prev, wrapped) = index.prev_translated_key(k1).unwrap(); assert!(wrapped); assert_eq!(prev.next().unwrap(), &3); assert_eq!(prev.next(), None); // Previous translated key is 0b. let (mut prev, wrapped) = index.prev_translated_key(&hex!("0x0c0102")).unwrap(); assert!(!wrapped); assert_eq!(prev.next().unwrap(), &1); assert_eq!(prev.next(), None); // Previous translated key is 1c. let (mut prev, wrapped) = index.prev_translated_key(&hex!("0x1d0102")).unwrap(); assert!(!wrapped); assert_eq!(prev.next().unwrap(), &22); assert_eq!(prev.next().unwrap(), &21); assert_eq!(prev.next(), None); // Previous translated key is 2d. let (mut prev, wrapped) = index.prev_translated_key(&hex!("0xCC0102")).unwrap(); assert!(!wrapped); assert_eq!(prev.next().unwrap(), &3); assert_eq!(prev.next(), None); // Last translated key is 2d. let mut last = index.last_translated_key().unwrap(); assert_eq!(last.next().unwrap(), &3); assert_eq!(last.next(), None); }); } }