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// Copyright 2013 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Pool is no-op under race detector, so all these tests do not work.
//
//go:build !race
package sync_test
import (
"runtime"
"runtime/debug"
"sort"
. "sync"
"sync/atomic"
"testing"
"time"
)
func TestPool(t *testing.T) {
// disable GC so we can control when it happens.
defer debug.SetGCPercent(debug.SetGCPercent(-1))
var p Pool
if p.Get() != nil {
t.Fatal("expected empty")
}
// Make sure that the goroutine doesn't migrate to another P
// between Put and Get calls.
Runtime_procPin()
p.Put("a")
p.Put("b")
if g := p.Get(); g != "a" {
t.Fatalf("got %#v; want a", g)
}
if g := p.Get(); g != "b" {
t.Fatalf("got %#v; want b", g)
}
if g := p.Get(); g != nil {
t.Fatalf("got %#v; want nil", g)
}
Runtime_procUnpin()
// Put in a large number of objects so they spill into
// stealable space.
for i := 0; i < 100; i++ {
p.Put("c")
}
// After one GC, the victim cache should keep them alive.
runtime.GC()
if g := p.Get(); g != "c" {
t.Fatalf("got %#v; want c after GC", g)
}
// A second GC should drop the victim cache.
runtime.GC()
if g := p.Get(); g != nil {
t.Fatalf("got %#v; want nil after second GC", g)
}
}
func TestPoolNew(t *testing.T) {
// disable GC so we can control when it happens.
defer debug.SetGCPercent(debug.SetGCPercent(-1))
i := 0
p := Pool{
New: func() any {
i++
return i
},
}
if v := p.Get(); v != 1 {
t.Fatalf("got %v; want 1", v)
}
if v := p.Get(); v != 2 {
t.Fatalf("got %v; want 2", v)
}
// Make sure that the goroutine doesn't migrate to another P
// between Put and Get calls.
Runtime_procPin()
p.Put(42)
if v := p.Get(); v != 42 {
t.Fatalf("got %v; want 42", v)
}
Runtime_procUnpin()
if v := p.Get(); v != 3 {
t.Fatalf("got %v; want 3", v)
}
}
// Test that Pool does not hold pointers to previously cached resources.
func TestPoolGC(t *testing.T) {
testPool(t, true)
}
// Test that Pool releases resources on GC.
func TestPoolRelease(t *testing.T) {
testPool(t, false)
}
func testPool(t *testing.T, drain bool) {
var p Pool
const N = 100
loop:
for try := 0; try < 3; try++ {
if try == 1 && testing.Short() {
break
}
var fin, fin1 uint32
for i := 0; i < N; i++ {
v := new(string)
runtime.SetFinalizer(v, func(vv *string) {
atomic.AddUint32(&fin, 1)
})
p.Put(v)
}
if drain {
for i := 0; i < N; i++ {
p.Get()
}
}
for i := 0; i < 5; i++ {
runtime.GC()
time.Sleep(time.Duration(i*100+10) * time.Millisecond)
// 1 pointer can remain on stack or elsewhere
if fin1 = atomic.LoadUint32(&fin); fin1 >= N-1 {
continue loop
}
}
t.Fatalf("only %v out of %v resources are finalized on try %v", fin1, N, try)
}
}
func TestPoolStress(t *testing.T) {
const P = 10
N := int(1e6)
if testing.Short() {
N /= 100
}
var p Pool
done := make(chan bool)
for i := 0; i < P; i++ {
go func() {
var v any = 0
for j := 0; j < N; j++ {
if v == nil {
v = 0
}
p.Put(v)
v = p.Get()
if v != nil && v.(int) != 0 {
t.Errorf("expect 0, got %v", v)
break
}
}
done <- true
}()
}
for i := 0; i < P; i++ {
<-done
}
}
func TestPoolDequeue(t *testing.T) {
testPoolDequeue(t, NewPoolDequeue(16))
}
func TestPoolChain(t *testing.T) {
testPoolDequeue(t, NewPoolChain())
}
func testPoolDequeue(t *testing.T, d PoolDequeue) {
const P = 10
var N int = 2e6
if testing.Short() {
N = 1e3
}
have := make([]int32, N)
var stop int32
var wg WaitGroup
record := func(val int) {
atomic.AddInt32(&have[val], 1)
if val == N-1 {
atomic.StoreInt32(&stop, 1)
}
}
// Start P-1 consumers.
for i := 1; i < P; i++ {
wg.Add(1)
go func() {
fail := 0
for atomic.LoadInt32(&stop) == 0 {
val, ok := d.PopTail()
if ok {
fail = 0
record(val.(int))
} else {
// Speed up the test by
// allowing the pusher to run.
if fail++; fail%100 == 0 {
runtime.Gosched()
}
}
}
wg.Done()
}()
}
// Start 1 producer.
nPopHead := 0
wg.Add(1)
go func() {
for j := 0; j < N; j++ {
for !d.PushHead(j) {
// Allow a popper to run.
runtime.Gosched()
}
if j%10 == 0 {
val, ok := d.PopHead()
if ok {
nPopHead++
record(val.(int))
}
}
}
wg.Done()
}()
wg.Wait()
// Check results.
for i, count := range have {
if count != 1 {
t.Errorf("expected have[%d] = 1, got %d", i, count)
}
}
// Check that at least some PopHeads succeeded. We skip this
// check in short mode because it's common enough that the
// queue will stay nearly empty all the time and a PopTail
// will happen during the window between every PushHead and
// PopHead.
if !testing.Short() && nPopHead == 0 {
t.Errorf("popHead never succeeded")
}
}
func TestNilPool(t *testing.T) {
catch := func() {
if recover() == nil {
t.Error("expected panic")
}
}
var p *Pool
t.Run("Get", func(t *testing.T) {
defer catch()
if p.Get() != nil {
t.Error("expected empty")
}
t.Error("should have panicked already")
})
t.Run("Put", func(t *testing.T) {
defer catch()
p.Put("a")
t.Error("should have panicked already")
})
}
func BenchmarkPool(b *testing.B) {
var p Pool
b.RunParallel(func(pb *testing.PB) {
for pb.Next() {
p.Put(1)
p.Get()
}
})
}
func BenchmarkPoolOverflow(b *testing.B) {
var p Pool
b.RunParallel(func(pb *testing.PB) {
for pb.Next() {
for b := 0; b < 100; b++ {
p.Put(1)
}
for b := 0; b < 100; b++ {
p.Get()
}
}
})
}
// Simulate object starvation in order to force Ps to steal objects
// from other Ps.
func BenchmarkPoolStarvation(b *testing.B) {
var p Pool
count := 100
// Reduce number of putted objects by 33 %. It creates objects starvation
// that force P-local storage to steal objects from other Ps.
countStarved := count - int(float32(count)*0.33)
b.RunParallel(func(pb *testing.PB) {
for pb.Next() {
for b := 0; b < countStarved; b++ {
p.Put(1)
}
for b := 0; b < count; b++ {
p.Get()
}
}
})
}
var globalSink any
func BenchmarkPoolSTW(b *testing.B) {
// Take control of GC.
defer debug.SetGCPercent(debug.SetGCPercent(-1))
var mstats runtime.MemStats
var pauses []uint64
var p Pool
for i := 0; i < b.N; i++ {
// Put a large number of items into a pool.
const N = 100000
var item any = 42
for i := 0; i < N; i++ {
p.Put(item)
}
// Do a GC.
runtime.GC()
// Record pause time.
runtime.ReadMemStats(&mstats)
pauses = append(pauses, mstats.PauseNs[(mstats.NumGC+255)%256])
}
// Get pause time stats.
sort.Slice(pauses, func(i, j int) bool { return pauses[i] < pauses[j] })
var total uint64
for _, ns := range pauses {
total += ns
}
// ns/op for this benchmark is average STW time.
b.ReportMetric(float64(total)/float64(b.N), "ns/op")
b.ReportMetric(float64(pauses[len(pauses)*95/100]), "p95-ns/STW")
b.ReportMetric(float64(pauses[len(pauses)*50/100]), "p50-ns/STW")
}
func BenchmarkPoolExpensiveNew(b *testing.B) {
// Populate a pool with items that are expensive to construct
// to stress pool cleanup and subsequent reconstruction.
// Create a ballast so the GC has a non-zero heap size and
// runs at reasonable times.
globalSink = make([]byte, 8<<20)
defer func() { globalSink = nil }()
// Create a pool that's "expensive" to fill.
var p Pool
var nNew uint64
p.New = func() any {
atomic.AddUint64(&nNew, 1)
time.Sleep(time.Millisecond)
return 42
}
var mstats1, mstats2 runtime.MemStats
runtime.ReadMemStats(&mstats1)
b.RunParallel(func(pb *testing.PB) {
// Simulate 100X the number of goroutines having items
// checked out from the Pool simultaneously.
items := make([]any, 100)
var sink []byte
for pb.Next() {
// Stress the pool.
for i := range items {
items[i] = p.Get()
// Simulate doing some work with this
// item checked out.
sink = make([]byte, 32<<10)
}
for i, v := range items {
p.Put(v)
items[i] = nil
}
}
_ = sink
})
runtime.ReadMemStats(&mstats2)
b.ReportMetric(float64(mstats2.NumGC-mstats1.NumGC)/float64(b.N), "GCs/op")
b.ReportMetric(float64(nNew)/float64(b.N), "New/op")
}
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