From 690713093b4726e26e2f533cc32f931f1bded547 Mon Sep 17 00:00:00 2001 From: Jeff Mitchell Date: Tue, 6 Jun 2023 16:11:44 -0400 Subject: [PATCH] Remove arc from main module --- arc.go | 268 ------------------------------------- arc_test.go | 378 ---------------------------------------------------- doc.go | 20 +-- 3 files changed, 10 insertions(+), 656 deletions(-) delete mode 100644 arc.go delete mode 100644 arc_test.go diff --git a/arc.go b/arc.go deleted file mode 100644 index 84c0b72..0000000 --- a/arc.go +++ /dev/null @@ -1,268 +0,0 @@ -// Copyright (c) HashiCorp, Inc. -// SPDX-License-Identifier: MPL-2.0 - -package lru - -import ( - "sync" - - "github.com/hashicorp/golang-lru/v2/simplelru" -) - -// ARCCache is a thread-safe fixed size Adaptive Replacement Cache (ARC). -// ARC is an enhancement over the standard LRU cache in that tracks both -// frequency and recency of use. This avoids a burst in access to new -// entries from evicting the frequently used older entries. It adds some -// additional tracking overhead to a standard LRU cache, computationally -// it is roughly 2x the cost, and the extra memory overhead is linear -// with the size of the cache. ARC has been patented by IBM, but is -// similar to the TwoQueueCache (2Q) which requires setting parameters. -type ARCCache[K comparable, V any] struct { - size int // Size is the total capacity of the cache - p int // P is the dynamic preference towards T1 or T2 - - t1 simplelru.LRUCache[K, V] // T1 is the LRU for recently accessed items - b1 simplelru.LRUCache[K, struct{}] // B1 is the LRU for evictions from t1 - - t2 simplelru.LRUCache[K, V] // T2 is the LRU for frequently accessed items - b2 simplelru.LRUCache[K, struct{}] // B2 is the LRU for evictions from t2 - - lock sync.RWMutex -} - -// NewARC creates an ARC of the given size -func NewARC[K comparable, V any](size int) (*ARCCache[K, V], error) { - // Create the sub LRUs - b1, err := simplelru.NewLRU[K, struct{}](size, nil) - if err != nil { - return nil, err - } - b2, err := simplelru.NewLRU[K, struct{}](size, nil) - if err != nil { - return nil, err - } - t1, err := simplelru.NewLRU[K, V](size, nil) - if err != nil { - return nil, err - } - t2, err := simplelru.NewLRU[K, V](size, nil) - if err != nil { - return nil, err - } - - // Initialize the ARC - c := &ARCCache[K, V]{ - size: size, - p: 0, - t1: t1, - b1: b1, - t2: t2, - b2: b2, - } - return c, nil -} - -// Get looks up a key's value from the cache. -func (c *ARCCache[K, V]) Get(key K) (value V, ok bool) { - c.lock.Lock() - defer c.lock.Unlock() - - // If the value is contained in T1 (recent), then - // promote it to T2 (frequent) - if val, ok := c.t1.Peek(key); ok { - c.t1.Remove(key) - c.t2.Add(key, val) - return val, ok - } - - // Check if the value is contained in T2 (frequent) - if val, ok := c.t2.Get(key); ok { - return val, ok - } - - // No hit - return -} - -// Add adds a value to the cache. -func (c *ARCCache[K, V]) Add(key K, value V) { - c.lock.Lock() - defer c.lock.Unlock() - - // Check if the value is contained in T1 (recent), and potentially - // promote it to frequent T2 - if c.t1.Contains(key) { - c.t1.Remove(key) - c.t2.Add(key, value) - return - } - - // Check if the value is already in T2 (frequent) and update it - if c.t2.Contains(key) { - c.t2.Add(key, value) - return - } - - // Check if this value was recently evicted as part of the - // recently used list - if c.b1.Contains(key) { - // T1 set is too small, increase P appropriately - delta := 1 - b1Len := c.b1.Len() - b2Len := c.b2.Len() - if b2Len > b1Len { - delta = b2Len / b1Len - } - if c.p+delta >= c.size { - c.p = c.size - } else { - c.p += delta - } - - // Potentially need to make room in the cache - if c.t1.Len()+c.t2.Len() >= c.size { - c.replace(false) - } - - // Remove from B1 - c.b1.Remove(key) - - // Add the key to the frequently used list - c.t2.Add(key, value) - return - } - - // Check if this value was recently evicted as part of the - // frequently used list - if c.b2.Contains(key) { - // T2 set is too small, decrease P appropriately - delta := 1 - b1Len := c.b1.Len() - b2Len := c.b2.Len() - if b1Len > b2Len { - delta = b1Len / b2Len - } - if delta >= c.p { - c.p = 0 - } else { - c.p -= delta - } - - // Potentially need to make room in the cache - if c.t1.Len()+c.t2.Len() >= c.size { - c.replace(true) - } - - // Remove from B2 - c.b2.Remove(key) - - // Add the key to the frequently used list - c.t2.Add(key, value) - return - } - - // Potentially need to make room in the cache - if c.t1.Len()+c.t2.Len() >= c.size { - c.replace(false) - } - - // Keep the size of the ghost buffers trim - if c.b1.Len() > c.size-c.p { - c.b1.RemoveOldest() - } - if c.b2.Len() > c.p { - c.b2.RemoveOldest() - } - - // Add to the recently seen list - c.t1.Add(key, value) -} - -// replace is used to adaptively evict from either T1 or T2 -// based on the current learned value of P -func (c *ARCCache[K, V]) replace(b2ContainsKey bool) { - t1Len := c.t1.Len() - if t1Len > 0 && (t1Len > c.p || (t1Len == c.p && b2ContainsKey)) { - k, _, ok := c.t1.RemoveOldest() - if ok { - c.b1.Add(k, struct{}{}) - } - } else { - k, _, ok := c.t2.RemoveOldest() - if ok { - c.b2.Add(k, struct{}{}) - } - } -} - -// Len returns the number of cached entries -func (c *ARCCache[K, V]) Len() int { - c.lock.RLock() - defer c.lock.RUnlock() - return c.t1.Len() + c.t2.Len() -} - -// Keys returns all the cached keys -func (c *ARCCache[K, V]) Keys() []K { - c.lock.RLock() - defer c.lock.RUnlock() - k1 := c.t1.Keys() - k2 := c.t2.Keys() - return append(k1, k2...) -} - -// Values returns all the cached values -func (c *ARCCache[K, V]) Values() []V { - c.lock.RLock() - defer c.lock.RUnlock() - v1 := c.t1.Values() - v2 := c.t2.Values() - return append(v1, v2...) -} - -// Remove is used to purge a key from the cache -func (c *ARCCache[K, V]) Remove(key K) { - c.lock.Lock() - defer c.lock.Unlock() - if c.t1.Remove(key) { - return - } - if c.t2.Remove(key) { - return - } - if c.b1.Remove(key) { - return - } - if c.b2.Remove(key) { - return - } -} - -// Purge is used to clear the cache -func (c *ARCCache[K, V]) Purge() { - c.lock.Lock() - defer c.lock.Unlock() - c.t1.Purge() - c.t2.Purge() - c.b1.Purge() - c.b2.Purge() -} - -// Contains is used to check if the cache contains a key -// without updating recency or frequency. -func (c *ARCCache[K, V]) Contains(key K) bool { - c.lock.RLock() - defer c.lock.RUnlock() - return c.t1.Contains(key) || c.t2.Contains(key) -} - -// Peek is used to inspect the cache value of a key -// without updating recency or frequency. -func (c *ARCCache[K, V]) Peek(key K) (value V, ok bool) { - c.lock.RLock() - defer c.lock.RUnlock() - if val, ok := c.t1.Peek(key); ok { - return val, ok - } - return c.t2.Peek(key) -} diff --git a/arc_test.go b/arc_test.go deleted file mode 100644 index 98190c8..0000000 --- a/arc_test.go +++ /dev/null @@ -1,378 +0,0 @@ -// Copyright (c) HashiCorp, Inc. -// SPDX-License-Identifier: MPL-2.0 - -package lru - -import ( - "math/rand" - "testing" - "time" -) - -func init() { - rand.Seed(time.Now().Unix()) -} - -func BenchmarkARC_Rand(b *testing.B) { - l, err := NewARC[int64, int64](8192) - if err != nil { - b.Fatalf("err: %v", err) - } - - trace := make([]int64, b.N*2) - for i := 0; i < b.N*2; i++ { - trace[i] = getRand(b) % 32768 - } - - b.ResetTimer() - - var hit, miss int - for i := 0; i < 2*b.N; i++ { - if i%2 == 0 { - l.Add(trace[i], trace[i]) - } else { - if _, ok := l.Get(trace[i]); ok { - hit++ - } else { - miss++ - } - } - } - b.Logf("hit: %d miss: %d ratio: %f", hit, miss, float64(hit)/float64(hit+miss)) -} - -func BenchmarkARC_Freq(b *testing.B) { - l, err := NewARC[int64, int64](8192) - if err != nil { - b.Fatalf("err: %v", err) - } - - trace := make([]int64, b.N*2) - for i := 0; i < b.N*2; i++ { - if i%2 == 0 { - trace[i] = getRand(b) % 16384 - } else { - trace[i] = getRand(b) % 32768 - } - } - - b.ResetTimer() - - for i := 0; i < b.N; i++ { - l.Add(trace[i], trace[i]) - } - var hit, miss int - for i := 0; i < b.N; i++ { - if _, ok := l.Get(trace[i]); ok { - hit++ - } else { - miss++ - } - } - b.Logf("hit: %d miss: %d ratio: %f", hit, miss, float64(hit)/float64(hit+miss)) -} - -func TestARC_RandomOps(t *testing.T) { - size := 128 - l, err := NewARC[int64, int64](128) - if err != nil { - t.Fatalf("err: %v", err) - } - - n := 200000 - for i := 0; i < n; i++ { - key := getRand(t) % 512 - r := getRand(t) - switch r % 3 { - case 0: - l.Add(key, key) - case 1: - l.Get(key) - case 2: - l.Remove(key) - } - - if l.t1.Len()+l.t2.Len() > size { - t.Fatalf("bad: t1: %d t2: %d b1: %d b2: %d p: %d", - l.t1.Len(), l.t2.Len(), l.b1.Len(), l.b2.Len(), l.p) - } - if l.b1.Len()+l.b2.Len() > size { - t.Fatalf("bad: t1: %d t2: %d b1: %d b2: %d p: %d", - l.t1.Len(), l.t2.Len(), l.b1.Len(), l.b2.Len(), l.p) - } - } -} - -func TestARC_Get_RecentToFrequent(t *testing.T) { - l, err := NewARC[int, int](128) - if err != nil { - t.Fatalf("err: %v", err) - } - - // Touch all the entries, should be in t1 - for i := 0; i < 128; i++ { - l.Add(i, i) - } - if n := l.t1.Len(); n != 128 { - t.Fatalf("bad: %d", n) - } - if n := l.t2.Len(); n != 0 { - t.Fatalf("bad: %d", n) - } - - // Get should upgrade to t2 - for i := 0; i < 128; i++ { - if _, ok := l.Get(i); !ok { - t.Fatalf("missing: %d", i) - } - } - if n := l.t1.Len(); n != 0 { - t.Fatalf("bad: %d", n) - } - if n := l.t2.Len(); n != 128 { - t.Fatalf("bad: %d", n) - } - - // Get be from t2 - for i := 0; i < 128; i++ { - if _, ok := l.Get(i); !ok { - t.Fatalf("missing: %d", i) - } - } - if n := l.t1.Len(); n != 0 { - t.Fatalf("bad: %d", n) - } - if n := l.t2.Len(); n != 128 { - t.Fatalf("bad: %d", n) - } -} - -func TestARC_Add_RecentToFrequent(t *testing.T) { - l, err := NewARC[int, int](128) - if err != nil { - t.Fatalf("err: %v", err) - } - - // Add initially to t1 - l.Add(1, 1) - if n := l.t1.Len(); n != 1 { - t.Fatalf("bad: %d", n) - } - if n := l.t2.Len(); n != 0 { - t.Fatalf("bad: %d", n) - } - - // Add should upgrade to t2 - l.Add(1, 1) - if n := l.t1.Len(); n != 0 { - t.Fatalf("bad: %d", n) - } - if n := l.t2.Len(); n != 1 { - t.Fatalf("bad: %d", n) - } - - // Add should remain in t2 - l.Add(1, 1) - if n := l.t1.Len(); n != 0 { - t.Fatalf("bad: %d", n) - } - if n := l.t2.Len(); n != 1 { - t.Fatalf("bad: %d", n) - } -} - -func TestARC_Adaptive(t *testing.T) { - l, err := NewARC[int, int](4) - if err != nil { - t.Fatalf("err: %v", err) - } - - // Fill t1 - for i := 0; i < 4; i++ { - l.Add(i, i) - } - if n := l.t1.Len(); n != 4 { - t.Fatalf("bad: %d", n) - } - - // Move to t2 - l.Get(0) - l.Get(1) - if n := l.t2.Len(); n != 2 { - t.Fatalf("bad: %d", n) - } - - // Evict from t1 - l.Add(4, 4) - if n := l.b1.Len(); n != 1 { - t.Fatalf("bad: %d", n) - } - - // Current state - // t1 : (MRU) [4, 3] (LRU) - // t2 : (MRU) [1, 0] (LRU) - // b1 : (MRU) [2] (LRU) - // b2 : (MRU) [] (LRU) - - // Add 2, should cause hit on b1 - l.Add(2, 2) - if n := l.b1.Len(); n != 1 { - t.Fatalf("bad: %d", n) - } - if l.p != 1 { - t.Fatalf("bad: %d", l.p) - } - if n := l.t2.Len(); n != 3 { - t.Fatalf("bad: %d", n) - } - - // Current state - // t1 : (MRU) [4] (LRU) - // t2 : (MRU) [2, 1, 0] (LRU) - // b1 : (MRU) [3] (LRU) - // b2 : (MRU) [] (LRU) - - // Add 4, should migrate to t2 - l.Add(4, 4) - if n := l.t1.Len(); n != 0 { - t.Fatalf("bad: %d", n) - } - if n := l.t2.Len(); n != 4 { - t.Fatalf("bad: %d", n) - } - - // Current state - // t1 : (MRU) [] (LRU) - // t2 : (MRU) [4, 2, 1, 0] (LRU) - // b1 : (MRU) [3] (LRU) - // b2 : (MRU) [] (LRU) - - // Add 4, should evict to b2 - l.Add(5, 5) - if n := l.t1.Len(); n != 1 { - t.Fatalf("bad: %d", n) - } - if n := l.t2.Len(); n != 3 { - t.Fatalf("bad: %d", n) - } - if n := l.b2.Len(); n != 1 { - t.Fatalf("bad: %d", n) - } - - // Current state - // t1 : (MRU) [5] (LRU) - // t2 : (MRU) [4, 2, 1] (LRU) - // b1 : (MRU) [3] (LRU) - // b2 : (MRU) [0] (LRU) - - // Add 0, should decrease p - l.Add(0, 0) - if n := l.t1.Len(); n != 0 { - t.Fatalf("bad: %d", n) - } - if n := l.t2.Len(); n != 4 { - t.Fatalf("bad: %d", n) - } - if n := l.b1.Len(); n != 2 { - t.Fatalf("bad: %d", n) - } - if n := l.b2.Len(); n != 0 { - t.Fatalf("bad: %d", n) - } - if l.p != 0 { - t.Fatalf("bad: %d", l.p) - } - - // Current state - // t1 : (MRU) [] (LRU) - // t2 : (MRU) [0, 4, 2, 1] (LRU) - // b1 : (MRU) [5, 3] (LRU) - // b2 : (MRU) [0] (LRU) -} - -func TestARC(t *testing.T) { - l, err := NewARC[int, int](128) - if err != nil { - t.Fatalf("err: %v", err) - } - - for i := 0; i < 256; i++ { - l.Add(i, i) - } - if l.Len() != 128 { - t.Fatalf("bad len: %v", l.Len()) - } - - for i, k := range l.Keys() { - if v, ok := l.Get(k); !ok || v != k || v != i+128 { - t.Fatalf("bad key: %v", k) - } - } - for i, v := range l.Values() { - if v != i+128 { - t.Fatalf("bad value: %v", v) - } - } - for i := 0; i < 128; i++ { - if _, ok := l.Get(i); ok { - t.Fatalf("should be evicted") - } - } - for i := 128; i < 256; i++ { - if _, ok := l.Get(i); !ok { - t.Fatalf("should not be evicted") - } - } - for i := 128; i < 192; i++ { - l.Remove(i) - if _, ok := l.Get(i); ok { - t.Fatalf("should be deleted") - } - } - - l.Purge() - if l.Len() != 0 { - t.Fatalf("bad len: %v", l.Len()) - } - if _, ok := l.Get(200); ok { - t.Fatalf("should contain nothing") - } -} - -// Test that Contains doesn't update recent-ness -func TestARC_Contains(t *testing.T) { - l, err := NewARC[int, int](2) - if err != nil { - t.Fatalf("err: %v", err) - } - - l.Add(1, 1) - l.Add(2, 2) - if !l.Contains(1) { - t.Errorf("1 should be contained") - } - - l.Add(3, 3) - if l.Contains(1) { - t.Errorf("Contains should not have updated recent-ness of 1") - } -} - -// Test that Peek doesn't update recent-ness -func TestARC_Peek(t *testing.T) { - l, err := NewARC[int, int](2) - if err != nil { - t.Fatalf("err: %v", err) - } - - l.Add(1, 1) - l.Add(2, 2) - if v, ok := l.Peek(1); !ok || v != 1 { - t.Errorf("1 should be set to 1: %v, %v", v, ok) - } - - l.Add(3, 3) - if l.Contains(1) { - t.Errorf("should not have updated recent-ness of 1") - } -} diff --git a/doc.go b/doc.go index 2474929..24107ee 100644 --- a/doc.go +++ b/doc.go @@ -3,21 +3,21 @@ // Package lru provides three different LRU caches of varying sophistication. // -// Cache is a simple LRU cache. It is based on the -// LRU implementation in groupcache: -// https://github.com/golang/groupcache/tree/master/lru +// Cache is a simple LRU cache. It is based on the LRU implementation in +// groupcache: https://github.com/golang/groupcache/tree/master/lru // // TwoQueueCache tracks frequently used and recently used entries separately. -// This avoids a burst of accesses from taking out frequently used entries, -// at the cost of about 2x computational overhead and some extra bookkeeping. +// This avoids a burst of accesses from taking out frequently used entries, at +// the cost of about 2x computational overhead and some extra bookkeeping. // -// ARCCache is an adaptive replacement cache. It tracks recent evictions as -// well as recent usage in both the frequent and recent caches. Its -// computational overhead is comparable to TwoQueueCache, but the memory -// overhead is linear with the size of the cache. +// ARCCache is an adaptive replacement cache. It tracks recent evictions as well +// as recent usage in both the frequent and recent caches. Its computational +// overhead is comparable to TwoQueueCache, but the memory overhead is linear +// with the size of the cache. // // ARC has been patented by IBM, so do not use it if that is problematic for -// your program. +// your program. For this reason, it is in a separate go module contained within +// this repository. // // All caches in this package take locks while operating, and are therefore // thread-safe for consumers.