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|
// Copyright 2024 Cloudflare, Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//! A In-memory cache implementation with TinyLFU as the admission policy and [S3-FIFO](https://s3fifo.com/) as the eviction policy.
//!
//! TinyUFO improves cache hit ratio noticeably compared to LRU.
//!
//! TinyUFO is lock-free. It is very fast in the systems with a lot concurrent reads and/or writes
use ahash::RandomState;
use crossbeam_queue::SegQueue;
use std::marker::PhantomData;
use std::sync::atomic::AtomicUsize;
use std::sync::atomic::{
AtomicBool, AtomicU8,
Ordering::{Acquire, Relaxed, SeqCst},
};
mod buckets;
mod estimation;
use buckets::Buckets;
use estimation::TinyLfu;
use std::hash::Hash;
const SMALL: bool = false;
const MAIN: bool = true;
// Indicate which queue an item is located
#[derive(Debug, Default)]
struct Location(AtomicBool);
impl Location {
fn new_small() -> Self {
Self(AtomicBool::new(SMALL))
}
fn value(&self) -> bool {
self.0.load(Relaxed)
}
fn is_main(&self) -> bool {
self.value()
}
fn move_to_main(&self) {
self.0.store(true, Relaxed);
}
}
// We have 8 bits to spare but we still cap at 3. This is to make sure that the main queue
// in the worst case can find something to evict quickly
const USES_CAP: u8 = 3;
#[derive(Debug, Default)]
struct Uses(AtomicU8);
impl Uses {
pub fn inc_uses(&self) -> u8 {
loop {
let uses = self.uses();
if uses >= USES_CAP {
return uses;
}
if let Err(new) = self.0.compare_exchange(uses, uses + 1, Acquire, Relaxed) {
// someone else beat us to it
if new >= USES_CAP {
// already above cap
return new;
} // else, try again
} else {
return uses + 1;
}
}
}
// decrease uses, return the previous value
pub fn decr_uses(&self) -> u8 {
loop {
let uses = self.uses();
if uses == 0 {
return 0;
}
if let Err(new) = self.0.compare_exchange(uses, uses - 1, Acquire, Relaxed) {
// someone else beat us to it
if new == 0 {
return 0;
} // else, try again
} else {
return uses;
}
}
}
pub fn uses(&self) -> u8 {
self.0.load(Relaxed)
}
}
type Key = u64;
type Weight = u16;
/// The key-value pair returned from cache eviction
#[derive(Clone)]
pub struct KV<T> {
/// NOTE: that we currently don't store the Actual key in the cache. This returned value
/// is just the hash of it.
pub key: Key,
pub data: T,
pub weight: Weight,
}
// the data and its metadata
pub struct Bucket<T> {
uses: Uses,
queue: Location,
weight: Weight,
data: T,
}
const SMALL_QUEUE_PERCENTAGE: f32 = 0.1;
struct FiFoQueues<T> {
total_weight_limit: usize,
small: SegQueue<Key>,
small_weight: AtomicUsize,
main: SegQueue<Key>,
main_weight: AtomicUsize,
// this replaces the ghost queue of S3-FIFO with similar goal: track the evicted assets
estimator: TinyLfu,
_t: PhantomData<T>,
}
impl<T: Clone + Send + Sync + 'static> FiFoQueues<T> {
fn admit(
&self,
key: Key,
data: T,
weight: u16,
ignore_lfu: bool,
buckets: &Buckets<T>,
) -> Vec<KV<T>> {
// Note that we only use TinyLFU during cache admission but not cache read.
// So effectively we mostly sketch the popularity of less popular assets.
// In this way the sketch is a bit more accurate on these assets.
// Also we don't need another separated window cache to address the sparse burst issue as
// this sketch doesn't favor very popular assets much.
let new_freq = self.estimator.incr(key);
assert!(weight > 0);
let new_bucket = {
let Some((uses, queue, weight)) = buckets.get_map(&key, |bucket| {
// the item exists, in case weight changes
let old_weight = bucket.weight;
let uses = bucket.uses.inc_uses();
fn update_atomic(weight: &AtomicUsize, old: u16, new: u16) {
if old == new {
return;
}
if old > new {
weight.fetch_sub((old - new) as usize, SeqCst);
} else {
weight.fetch_add((new - old) as usize, SeqCst);
}
}
let queue = bucket.queue.is_main();
if queue == MAIN {
update_atomic(&self.main_weight, old_weight, weight);
} else {
update_atomic(&self.small_weight, old_weight, weight);
}
(uses, queue, weight)
}) else {
let mut evicted = self.evict_to_limit(weight, buckets);
// TODO: figure out the right way to compare frequencies of different weights across
// many evicted assets. For now TinyLFU is only used when only evicting 1 item.
let (key, data, weight) = if !ignore_lfu && evicted.len() == 1 {
// Apply the admission algorithm of TinyLFU: compare the incoming new item
// and the evicted one. The more popular one is admitted to cache
let evicted_first = &evicted[0];
let evicted_freq = self.estimator.get(evicted_first.key);
if evicted_freq > new_freq {
// put it back
let first = evicted.pop().expect("just check non-empty");
// return the put value
evicted.push(KV { key, data, weight });
(first.key, first.data, first.weight)
} else {
(key, data, weight)
}
} else {
(key, data, weight)
};
let bucket = Bucket {
queue: Location::new_small(),
weight,
uses: Default::default(), // 0
data,
};
let old = buckets.insert(key, bucket);
if old.is_none() {
// Always push key first before updating weight
// If doing the other order, another concurrent thread might not
// find things to evict
self.small.push(key);
self.small_weight.fetch_add(weight as usize, SeqCst);
} // else: two threads are racing adding the item
// TODO: compare old.weight and update accordingly
return evicted;
};
Bucket {
queue: Location(queue.into()),
weight,
uses: Uses(uses.into()),
data,
}
};
// replace the existing one
buckets.insert(key, new_bucket);
// NOTE: there is a chance that the item itself is evicted if it happens to be the one selected
// by the algorithm. We could avoid this by checking if the item is in the returned evicted items,
// and then add it back. But to keep the code simple we just allow it to happen.
self.evict_to_limit(0, buckets)
}
// the `extra_weight` is to essentially tell the cache to reserve that amount of weight for
// admission. It is used when calling `evict_to_limit` before admitting the asset itself.
fn evict_to_limit(&self, extra_weight: Weight, buckets: &Buckets<T>) -> Vec<KV<T>> {
let mut evicted = if self.total_weight_limit
< self.small_weight.load(SeqCst) + self.main_weight.load(SeqCst) + extra_weight as usize
{
Vec::with_capacity(1)
} else {
vec![]
};
while self.total_weight_limit
< self.small_weight.load(SeqCst) + self.main_weight.load(SeqCst) + extra_weight as usize
{
if let Some(evicted_item) = self.evict_one(buckets) {
evicted.push(evicted_item);
} else {
break;
}
}
evicted
}
fn evict_one(&self, buckets: &Buckets<T>) -> Option<KV<T>> {
let evict_small = self.small_weight_limit() <= self.small_weight.load(SeqCst);
if evict_small {
let evicted = self.evict_one_from_small(buckets);
// evict_one_from_small could just promote everything to main without evicting any
// so need to evict_one_from_main if nothing evicted
if evicted.is_some() {
return evicted;
}
}
self.evict_one_from_main(buckets)
}
fn small_weight_limit(&self) -> usize {
(self.total_weight_limit as f32 * SMALL_QUEUE_PERCENTAGE).floor() as usize + 1
}
fn evict_one_from_small(&self, buckets: &Buckets<T>) -> Option<KV<T>> {
loop {
let Some(to_evict) = self.small.pop() else {
// empty queue, this is caught between another pop() and fetch_sub()
return None;
};
let v = buckets
.get_map(&to_evict, |bucket| {
let weight = bucket.weight;
self.small_weight.fetch_sub(weight as usize, SeqCst);
if bucket.uses.uses() > 1 {
// move to main
bucket.queue.move_to_main();
self.main.push(to_evict);
self.main_weight.fetch_add(weight as usize, SeqCst);
// continue until find one to evict
None
} else {
let data = bucket.data.clone();
let weight = bucket.weight;
buckets.remove(&to_evict);
Some(KV {
key: to_evict,
data,
weight,
})
}
})
.flatten();
if v.is_some() {
// found the one to evict, break
return v;
}
}
}
fn evict_one_from_main(&self, buckets: &Buckets<T>) -> Option<KV<T>> {
loop {
let to_evict = self.main.pop()?;
if let Some(v) = buckets
.get_map(&to_evict, |bucket| {
if bucket.uses.decr_uses() > 0 {
// put it back
self.main.push(to_evict);
// continue the loop
None
} else {
// evict
let weight = bucket.weight;
self.main_weight.fetch_sub(weight as usize, SeqCst);
let data = bucket.data.clone();
buckets.remove(&to_evict);
Some(KV {
key: to_evict,
data,
weight,
})
}
})
.flatten()
{
// found the one to evict, break
return Some(v);
}
}
}
}
/// [TinyUfo] cache
pub struct TinyUfo<K, T> {
queues: FiFoQueues<T>,
buckets: Buckets<T>,
random_status: RandomState,
_k: PhantomData<K>,
}
impl<K: Hash, T: Clone + Send + Sync + 'static> TinyUfo<K, T> {
/// Create a new TinyUfo cache with the given weight limit and the given
/// size limit of the ghost queue.
pub fn new(total_weight_limit: usize, estimated_size: usize) -> Self {
let queues = FiFoQueues {
small: SegQueue::new(),
small_weight: 0.into(),
main: SegQueue::new(),
main_weight: 0.into(),
total_weight_limit,
estimator: TinyLfu::new(estimated_size),
_t: PhantomData,
};
TinyUfo {
queues,
buckets: Buckets::new_fast(estimated_size),
random_status: RandomState::new(),
_k: PhantomData,
}
}
/// Create a new TinyUfo cache but with more memory efficient data structures.
/// The trade-off is that the the get() is slower by a constant factor.
/// The cache hit ratio could be higher as this type of TinyUFO allows to store
/// more assets with the same memory.
pub fn new_compact(total_weight_limit: usize, estimated_size: usize) -> Self {
let queues = FiFoQueues {
small: SegQueue::new(),
small_weight: 0.into(),
main: SegQueue::new(),
main_weight: 0.into(),
total_weight_limit,
estimator: TinyLfu::new_compact(estimated_size),
_t: PhantomData,
};
TinyUfo {
queues,
buckets: Buckets::new_compact(estimated_size, 32),
random_status: RandomState::new(),
_k: PhantomData,
}
}
// TODO: with_capacity()
/// Read the given key
///
/// Return Some(T) if the key exists
pub fn get(&self, key: &K) -> Option<T> {
let key = self.random_status.hash_one(key);
self.buckets.get_map(&key, |p| {
p.uses.inc_uses();
p.data.clone()
})
}
/// Put the key value to the [TinyUfo]
///
/// Return a list of [KV] of key and `T` that are evicted
pub fn put(&self, key: K, data: T, weight: Weight) -> Vec<KV<T>> {
let key = self.random_status.hash_one(&key);
self.queues.admit(key, data, weight, false, &self.buckets)
}
/// Remove the given key from the cache if it exists
///
/// Returns Some(T) if the key was found and removed, None otherwise
pub fn remove(&self, key: &K) -> Option<T> {
let key = self.random_status.hash_one(key);
// Get data and update weights
let result = self.buckets.get_map(&key, |bucket| {
let data = bucket.data.clone();
let weight = bucket.weight;
// Update weight based on queue location
if bucket.queue.is_main() {
self.queues.main_weight.fetch_sub(weight as usize, SeqCst);
} else {
self.queues.small_weight.fetch_sub(weight as usize, SeqCst);
}
data
});
// If we found and processed the item, remove it from buckets
if result.is_some() {
self.buckets.remove(&key);
}
result
}
/// Always put the key value to the [TinyUfo]
///
/// Return a list of [KV] of key and `T` that are evicted
///
/// Similar to [Self::put] but guarantee the assertion of the asset.
/// In [Self::put], the TinyLFU check may reject putting the current asset if it is less
/// popular than the once being evicted.
///
/// In some real world use cases, a few reads to the same asset may be pending for the put action
/// to be finished so that they can read the asset from cache. Neither the above behaviors are ideal
/// for this use case.
///
/// Compared to [Self::put], the hit ratio when using this function is reduced by about 0.5pp or less in
/// under zipf workloads.
pub fn force_put(&self, key: K, data: T, weight: Weight) -> Vec<KV<T>> {
let key = self.random_status.hash_one(&key);
self.queues.admit(key, data, weight, true, &self.buckets)
}
#[cfg(test)]
fn peek_queue(&self, key: K) -> Option<bool> {
let key = self.random_status.hash_one(&key);
self.buckets.get_queue(&key)
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_uses() {
let uses: Uses = Default::default();
assert_eq!(uses.uses(), 0);
uses.inc_uses();
assert_eq!(uses.uses(), 1);
for _ in 0..USES_CAP {
uses.inc_uses();
}
assert_eq!(uses.uses(), USES_CAP);
for _ in 0..USES_CAP + 2 {
uses.decr_uses();
}
assert_eq!(uses.uses(), 0);
}
#[test]
fn test_evict_from_small() {
let mut cache = TinyUfo::new(5, 5);
cache.random_status = RandomState::with_seeds(2, 3, 4, 5);
cache.queues.estimator = TinyLfu::new_seeded(5);
cache.put(1, 1, 1);
cache.put(2, 2, 2);
cache.put(3, 3, 2);
// cache full now
assert_eq!(cache.peek_queue(1), Some(SMALL));
assert_eq!(cache.peek_queue(2), Some(SMALL));
assert_eq!(cache.peek_queue(3), Some(SMALL));
let evicted = cache.put(4, 4, 3);
assert_eq!(evicted.len(), 2);
assert_eq!(evicted[0].data, 1);
assert_eq!(evicted[1].data, 2);
assert_eq!(cache.peek_queue(1), None);
assert_eq!(cache.peek_queue(2), None);
assert_eq!(cache.peek_queue(3), Some(SMALL));
}
#[test]
fn test_evict_from_small_to_main() {
let mut cache = TinyUfo::new(5, 5);
cache.random_status = RandomState::with_seeds(2, 3, 4, 5);
cache.queues.estimator = TinyLfu::new_seeded(5);
cache.put(1, 1, 1);
cache.put(2, 2, 2);
cache.put(3, 3, 2);
// cache full now
cache.get(&1);
cache.get(&1); // 1 will be moved to main during next eviction
assert_eq!(cache.peek_queue(1), Some(SMALL));
assert_eq!(cache.peek_queue(2), Some(SMALL));
assert_eq!(cache.peek_queue(3), Some(SMALL));
let evicted = cache.put(4, 4, 2);
assert_eq!(evicted.len(), 1);
assert_eq!(evicted[0].weight, 2);
assert_eq!(cache.peek_queue(1), Some(MAIN));
// either 2, 3, or 4 was evicted. Check evicted for which.
let mut remaining = vec![2, 3, 4];
remaining.remove(
remaining
.iter()
.position(|x| *x == evicted[0].data)
.unwrap(),
);
assert_eq!(cache.peek_queue(evicted[0].key), None);
for k in remaining {
assert_eq!(cache.peek_queue(k), Some(SMALL));
}
}
#[test]
fn test_evict_reentry() {
let mut cache = TinyUfo::new(5, 5);
cache.random_status = RandomState::with_seeds(2, 3, 4, 5);
cache.queues.estimator = TinyLfu::new_seeded(5);
cache.put(1, 1, 1);
cache.put(2, 2, 2);
cache.put(3, 3, 2);
// cache full now
assert_eq!(cache.peek_queue(1), Some(SMALL));
assert_eq!(cache.peek_queue(2), Some(SMALL));
assert_eq!(cache.peek_queue(3), Some(SMALL));
let evicted = cache.put(4, 4, 1);
assert_eq!(evicted.len(), 1);
assert_eq!(evicted[0].data, 1);
assert_eq!(cache.peek_queue(1), None);
assert_eq!(cache.peek_queue(2), Some(SMALL));
assert_eq!(cache.peek_queue(3), Some(SMALL));
assert_eq!(cache.peek_queue(4), Some(SMALL));
let evicted = cache.put(1, 1, 1);
assert_eq!(evicted.len(), 1);
assert_eq!(evicted[0].data, 2);
assert_eq!(cache.peek_queue(1), Some(SMALL));
assert_eq!(cache.peek_queue(2), None);
assert_eq!(cache.peek_queue(3), Some(SMALL));
assert_eq!(cache.peek_queue(4), Some(SMALL));
}
#[test]
fn test_evict_entry_denied() {
let mut cache = TinyUfo::new(5, 5);
cache.random_status = RandomState::with_seeds(2, 3, 4, 5);
cache.queues.estimator = TinyLfu::new_seeded(5);
cache.put(1, 1, 1);
cache.put(2, 2, 2);
cache.put(3, 3, 2);
// cache full now
assert_eq!(cache.peek_queue(1), Some(SMALL));
assert_eq!(cache.peek_queue(2), Some(SMALL));
assert_eq!(cache.peek_queue(3), Some(SMALL));
// trick: put a few times to bump their frequencies
cache.put(1, 1, 1);
cache.put(2, 2, 2);
cache.put(3, 3, 2);
let evicted = cache.put(4, 4, 1);
assert_eq!(evicted.len(), 1);
assert_eq!(evicted[0].data, 4); // 4 is returned
assert_eq!(cache.peek_queue(1), Some(SMALL));
assert_eq!(cache.peek_queue(2), Some(SMALL));
assert_eq!(cache.peek_queue(3), Some(SMALL));
assert_eq!(cache.peek_queue(4), None);
}
#[test]
fn test_force_put() {
let mut cache = TinyUfo::new(5, 5);
cache.random_status = RandomState::with_seeds(2, 3, 4, 5);
cache.queues.estimator = TinyLfu::new_seeded(5);
cache.put(1, 1, 1);
cache.put(2, 2, 2);
cache.put(3, 3, 2);
// cache full now
assert_eq!(cache.peek_queue(1), Some(SMALL));
assert_eq!(cache.peek_queue(2), Some(SMALL));
assert_eq!(cache.peek_queue(3), Some(SMALL));
// trick: put a few times to bump their frequencies
cache.put(1, 1, 1);
cache.put(2, 2, 2);
cache.put(3, 3, 2);
// force put will replace 1 with 4 even through 1 is more popular
let evicted = cache.force_put(4, 4, 1);
assert_eq!(evicted.len(), 1);
assert_eq!(evicted[0].data, 1); // 1 is returned
assert_eq!(cache.peek_queue(1), None);
assert_eq!(cache.peek_queue(2), Some(SMALL));
assert_eq!(cache.peek_queue(3), Some(SMALL));
assert_eq!(cache.peek_queue(4), Some(SMALL));
}
#[test]
fn test_evict_from_main() {
let mut cache = TinyUfo::new(5, 5);
cache.random_status = RandomState::with_seeds(2, 3, 4, 5);
cache.queues.estimator = TinyLfu::new_seeded(5);
cache.put(1, 1, 1);
cache.put(2, 2, 2);
cache.put(3, 3, 2);
// cache full now
// all 3 will qualify to main
cache.get(&1);
cache.get(&1);
cache.get(&2);
cache.get(&2);
cache.get(&3);
cache.get(&3);
let evicted = cache.put(4, 4, 1);
assert_eq!(evicted.len(), 1);
assert_eq!(evicted[0].data, 1);
// 1 kicked from main
assert_eq!(cache.peek_queue(1), None);
assert_eq!(cache.peek_queue(2), Some(MAIN));
assert_eq!(cache.peek_queue(3), Some(MAIN));
assert_eq!(cache.peek_queue(4), Some(SMALL));
let evicted = cache.put(1, 1, 1);
assert_eq!(evicted.len(), 1);
assert_eq!(evicted[0].data, 4);
assert_eq!(cache.peek_queue(1), Some(SMALL));
assert_eq!(cache.peek_queue(2), Some(MAIN));
assert_eq!(cache.peek_queue(3), Some(MAIN));
assert_eq!(cache.peek_queue(4), None);
}
#[test]
fn test_evict_from_small_compact() {
let mut cache = TinyUfo::new(5, 5);
cache.random_status = RandomState::with_seeds(2, 3, 4, 5);
cache.queues.estimator = TinyLfu::new_compact_seeded(5);
cache.put(1, 1, 1);
cache.put(2, 2, 2);
cache.put(3, 3, 2);
// cache full now
assert_eq!(cache.peek_queue(1), Some(SMALL));
assert_eq!(cache.peek_queue(2), Some(SMALL));
assert_eq!(cache.peek_queue(3), Some(SMALL));
let evicted = cache.put(4, 4, 3);
assert_eq!(evicted.len(), 2);
assert_eq!(evicted[0].data, 1);
assert_eq!(evicted[1].data, 2);
assert_eq!(cache.peek_queue(1), None);
assert_eq!(cache.peek_queue(2), None);
assert_eq!(cache.peek_queue(3), Some(SMALL));
}
#[test]
fn test_evict_from_small_to_main_compact() {
let mut cache = TinyUfo::new(5, 5);
cache.random_status = RandomState::with_seeds(2, 3, 4, 5);
cache.queues.estimator = TinyLfu::new_compact_seeded(5);
cache.put(1, 1, 1);
cache.put(2, 2, 2);
cache.put(3, 3, 2);
// cache full now
cache.get(&1);
cache.get(&1); // 1 will be moved to main during next eviction
assert_eq!(cache.peek_queue(1), Some(SMALL));
assert_eq!(cache.peek_queue(2), Some(SMALL));
assert_eq!(cache.peek_queue(3), Some(SMALL));
let evicted = cache.put(4, 4, 2);
assert_eq!(evicted.len(), 1);
assert_eq!(evicted[0].weight, 2);
assert_eq!(cache.peek_queue(1), Some(MAIN));
// either 2, 3, or 4 was evicted. Check evicted for which.
let mut remaining = vec![2, 3, 4];
remaining.remove(
remaining
.iter()
.position(|x| *x == evicted[0].data)
.unwrap(),
);
assert_eq!(cache.peek_queue(evicted[0].key), None);
for k in remaining {
assert_eq!(cache.peek_queue(k), Some(SMALL));
}
}
#[test]
fn test_remove() {
let mut cache = TinyUfo::new(5, 5);
cache.random_status = RandomState::with_seeds(2, 3, 4, 5);
cache.put(1, 1, 1);
cache.put(2, 2, 2);
cache.put(3, 3, 2);
assert_eq!(cache.remove(&1), Some(1));
assert_eq!(cache.remove(&3), Some(3));
assert_eq!(cache.get(&1), None);
assert_eq!(cache.get(&3), None);
// Verify empty keys get evicted when cache fills up
// Fill cache to trigger eviction
cache.put(5, 5, 2);
cache.put(6, 6, 2);
cache.put(7, 7, 2);
// The removed items (1, 3) should be naturally evicted now
// and new items should be in cache
assert_eq!(cache.get(&1), None);
assert_eq!(cache.get(&3), None);
assert!(cache.get(&5).is_some() || cache.get(&6).is_some() || cache.get(&7).is_some());
// Test weights after eviction cycles
let total_weight =
cache.queues.small_weight.load(SeqCst) + cache.queues.main_weight.load(SeqCst);
assert!(total_weight <= 5); // Should not exceed limit
}
}
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