libgo/go/sync/map_test.go - gofrontend - Git at Google

 // Copyright 2016 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.

 package sync_test

 import (
 	"math/rand"
 	"reflect"
 	"runtime"
 	"sync"
 	"sync/atomic"
 	"testing"
 	"testing/quick"
 )

 type mapOp string

 const (
 	opLoad          = mapOp("Load")
 	opStore         = mapOp("Store")
 	opLoadOrStore   = mapOp("LoadOrStore")
 	opLoadAndDelete = mapOp("LoadAndDelete")
 	opDelete        = mapOp("Delete")
 )

 var mapOps = [...]mapOp{opLoad, opStore, opLoadOrStore, opLoadAndDelete, opDelete}

 // mapCall is a quick.Generator for calls on mapInterface.
 type mapCall struct {
 	op   mapOp
 	k, v any
 }

 func (c mapCall) apply(m mapInterface) (any, bool) {
 	switch c.op {
 	case opLoad:
 		return m.Load(c.k)
 	case opStore:
 		m.Store(c.k, c.v)
 		return nil, false
 	case opLoadOrStore:
 		return m.LoadOrStore(c.k, c.v)
 	case opLoadAndDelete:
 		return m.LoadAndDelete(c.k)
 	case opDelete:
 		m.Delete(c.k)
 		return nil, false
 	default:
 		panic("invalid mapOp")
 	}
 }

 type mapResult struct {
 	value any
 	ok    bool
 }

 func randValue(r *rand.Rand) any {
 	b := make([]byte, r.Intn(4))
 	for i := range b {
 		b[i] = 'a' + byte(rand.Intn(26))
 	}
 	return string(b)
 }

 func (mapCall) Generate(r *rand.Rand, size int) reflect.Value {
 	c := mapCall{op: mapOps[rand.Intn(len(mapOps))], k: randValue(r)}
 	switch c.op {
 	case opStore, opLoadOrStore:
 		c.v = randValue(r)
 	}
 	return reflect.ValueOf(c)
 }

 func applyCalls(m mapInterface, calls []mapCall) (results []mapResult, final map[any]any) {
 	for _, c := range calls {
 		v, ok := c.apply(m)
 		results = append(results, mapResult{v, ok})
 	}

 	final = make(map[any]any)
 	m.Range(func(k, v any) bool {
 		final[k] = v
 		return true
 	})

 	return results, final
 }

 func applyMap(calls []mapCall) ([]mapResult, map[any]any) {
 	return applyCalls(new(sync.Map), calls)
 }

 func applyRWMutexMap(calls []mapCall) ([]mapResult, map[any]any) {
 	return applyCalls(new(RWMutexMap), calls)
 }

 func applyDeepCopyMap(calls []mapCall) ([]mapResult, map[any]any) {
 	return applyCalls(new(DeepCopyMap), calls)
 }

 func TestMapMatchesRWMutex(t *testing.T) {
 	if err := quick.CheckEqual(applyMap, applyRWMutexMap, nil); err != nil {
 		t.Error(err)
 	}
 }

 func TestMapMatchesDeepCopy(t *testing.T) {
 	if err := quick.CheckEqual(applyMap, applyDeepCopyMap, nil); err != nil {
 		t.Error(err)
 	}
 }

 func TestConcurrentRange(t *testing.T) {
 	const mapSize = 1 << 10

 	m := new(sync.Map)
 	for n := int64(1); n <= mapSize; n++ {
 		m.Store(n, int64(n))
 	}

 	done := make(chan struct{})
 	var wg sync.WaitGroup
 	defer func() {
 		close(done)
 		wg.Wait()
 	}()
 	for g := int64(runtime.GOMAXPROCS(0)); g > 0; g-- {
 		r := rand.New(rand.NewSource(g))
 		wg.Add(1)
 		go func(g int64) {
 			defer wg.Done()
 			for i := int64(0); ; i++ {
 				select {
 				case <-done:
 					return
 				default:
 				}
 				for n := int64(1); n < mapSize; n++ {
 					if r.Int63n(mapSize) == 0 {
 						m.Store(n, n*i*g)
 					} else {
 						m.Load(n)
 					}
 				}
 			}
 		}(g)
 	}

 	iters := 1 << 10
 	if testing.Short() {
 		iters = 16
 	}
 	for n := iters; n > 0; n-- {
 		seen := make(map[int64]bool, mapSize)

 		m.Range(func(ki, vi any) bool {
 			k, v := ki.(int64), vi.(int64)
 			if v%k != 0 {
 				t.Fatalf("while Storing multiples of %v, Range saw value %v", k, v)
 			}
 			if seen[k] {
 				t.Fatalf("Range visited key %v twice", k)
 			}
 			seen[k] = true
 			return true
 		})

 		if len(seen) != mapSize {
 			t.Fatalf("Range visited %v elements of %v-element Map", len(seen), mapSize)
 		}
 	}
 }

 func TestIssue40999(t *testing.T) {
 	var m sync.Map

 	// Since the miss-counting in missLocked (via Delete)
 	// compares the miss count with len(m.dirty),
 	// add an initial entry to bias len(m.dirty) above the miss count.
 	m.Store(nil, struct{}{})

 	var finalized uint32

 	// Set finalizers that count for collected keys. A non-zero count
 	// indicates that keys have not been leaked.
 	for atomic.LoadUint32(&finalized) == 0 {
 		p := new(int)
 		runtime.SetFinalizer(p, func(*int) {
 			atomic.AddUint32(&finalized, 1)
 		})
 		m.Store(p, struct{}{})
 		m.Delete(p)
 		runtime.GC()
 	}
 }

 func TestMapRangeNestedCall(t *testing.T) { // Issue 46399
 	var m sync.Map
 	for i, v := range [3]string{"hello", "world", "Go"} {
 		m.Store(i, v)
 	}
 	m.Range(func(key, value any) bool {
 		m.Range(func(key, value any) bool {
 			// We should be able to load the key offered in the Range callback,
 			// because there are no concurrent Delete involved in this tested map.
 			if v, ok := m.Load(key); !ok || !reflect.DeepEqual(v, value) {
 				t.Fatalf("Nested Range loads unexpected value, got %+v want %+v", v, value)
 			}

 			// We didn't keep 42 and a value into the map before, if somehow we loaded
 			// a value from such a key, meaning there must be an internal bug regarding
 			// nested range in the Map.
 			if _, loaded := m.LoadOrStore(42, "dummy"); loaded {
 				t.Fatalf("Nested Range loads unexpected value, want store a new value")
 			}

 			// Try to Store then LoadAndDelete the corresponding value with the key
 			// 42 to the Map. In this case, the key 42 and associated value should be
 			// removed from the Map. Therefore any future range won't observe key 42
 			// as we checked in above.
 			val := "sync.Map"
 			m.Store(42, val)
 			if v, loaded := m.LoadAndDelete(42); !loaded || !reflect.DeepEqual(v, val) {
 				t.Fatalf("Nested Range loads unexpected value, got %v, want %v", v, val)
 			}
 			return true
 		})

 		// Remove key from Map on-the-fly.
 		m.Delete(key)
 		return true
 	})

 	// After a Range of Delete, all keys should be removed and any
 	// further Range won't invoke the callback. Hence length remains 0.
 	length := 0
 	m.Range(func(key, value any) bool {
 		length++
 		return true
 	})

 	if length != 0 {
 		t.Fatalf("Unexpected sync.Map size, got %v want %v", length, 0)
 	}
 }
	// Copyright 2016 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.

	package sync_test

	import (
	"math/rand"
	"reflect"
	"runtime"
	"sync"
	"sync/atomic"
	"testing"
	"testing/quick"
	)

	type mapOp string

	const (
	opLoad = mapOp("Load")
	opStore = mapOp("Store")
	opLoadOrStore = mapOp("LoadOrStore")
	opLoadAndDelete = mapOp("LoadAndDelete")
	opDelete = mapOp("Delete")
	)

	var mapOps = [...]mapOp{opLoad, opStore, opLoadOrStore, opLoadAndDelete, opDelete}

	// mapCall is a quick.Generator for calls on mapInterface.
	type mapCall struct {
	op mapOp
	k, v any
	}

	func (c mapCall) apply(m mapInterface) (any, bool) {
	switch c.op {
	case opLoad:
	return m.Load(c.k)
	case opStore:
	m.Store(c.k, c.v)
	return nil, false
	case opLoadOrStore:
	return m.LoadOrStore(c.k, c.v)
	case opLoadAndDelete:
	return m.LoadAndDelete(c.k)
	case opDelete:
	m.Delete(c.k)
	return nil, false
	default:
	panic("invalid mapOp")
	}
	}

	type mapResult struct {
	value any
	ok bool
	}

	func randValue(r *rand.Rand) any {
	b := make([]byte, r.Intn(4))
	for i := range b {
	b[i] = 'a' + byte(rand.Intn(26))
	}
	return string(b)
	}

	func (mapCall) Generate(r *rand.Rand, size int) reflect.Value {
	c := mapCall{op: mapOps[rand.Intn(len(mapOps))], k: randValue(r)}
	switch c.op {
	case opStore, opLoadOrStore:
	c.v = randValue(r)
	}
	return reflect.ValueOf(c)
	}

	func applyCalls(m mapInterface, calls []mapCall) (results []mapResult, final map[any]any) {
	for _, c := range calls {
	v, ok := c.apply(m)
	results = append(results, mapResult{v, ok})
	}

	final = make(map[any]any)
	m.Range(func(k, v any) bool {
	final[k] = v
	return true
	})

	return results, final
	}

	func applyMap(calls []mapCall) ([]mapResult, map[any]any) {
	return applyCalls(new(sync.Map), calls)
	}

	func applyRWMutexMap(calls []mapCall) ([]mapResult, map[any]any) {
	return applyCalls(new(RWMutexMap), calls)
	}

	func applyDeepCopyMap(calls []mapCall) ([]mapResult, map[any]any) {
	return applyCalls(new(DeepCopyMap), calls)
	}

	func TestMapMatchesRWMutex(t *testing.T) {
	if err := quick.CheckEqual(applyMap, applyRWMutexMap, nil); err != nil {
	t.Error(err)
	}
	}

	func TestMapMatchesDeepCopy(t *testing.T) {
	if err := quick.CheckEqual(applyMap, applyDeepCopyMap, nil); err != nil {
	t.Error(err)
	}
	}

	func TestConcurrentRange(t *testing.T) {
	const mapSize = 1 << 10

	m := new(sync.Map)
	for n := int64(1); n <= mapSize; n++ {
	m.Store(n, int64(n))
	}

	done := make(chan struct{})
	var wg sync.WaitGroup
	defer func() {
	close(done)
	wg.Wait()
	}()
	for g := int64(runtime.GOMAXPROCS(0)); g > 0; g-- {
	r := rand.New(rand.NewSource(g))
	wg.Add(1)
	go func(g int64) {
	defer wg.Done()
	for i := int64(0); ; i++ {
	select {
	case <-done:
	return
	default:
	}
	for n := int64(1); n < mapSize; n++ {
	if r.Int63n(mapSize) == 0 {
	m.Store(n, nig)
	} else {
	m.Load(n)
	}
	}
	}
	}(g)
	}

	iters := 1 << 10
	if testing.Short() {
	iters = 16
	}
	for n := iters; n > 0; n-- {
	seen := make(map[int64]bool, mapSize)

	m.Range(func(ki, vi any) bool {
	k, v := ki.(int64), vi.(int64)
	if v%k != 0 {
	t.Fatalf("while Storing multiples of %v, Range saw value %v", k, v)
	}
	if seen[k] {
	t.Fatalf("Range visited key %v twice", k)
	}
	seen[k] = true
	return true
	})

	if len(seen) != mapSize {
	t.Fatalf("Range visited %v elements of %v-element Map", len(seen), mapSize)
	}
	}
	}

	func TestIssue40999(t *testing.T) {
	var m sync.Map

	// Since the miss-counting in missLocked (via Delete)
	// compares the miss count with len(m.dirty),
	// add an initial entry to bias len(m.dirty) above the miss count.
	m.Store(nil, struct{}{})

	var finalized uint32

	// Set finalizers that count for collected keys. A non-zero count
	// indicates that keys have not been leaked.
	for atomic.LoadUint32(&finalized) == 0 {
	p := new(int)
	runtime.SetFinalizer(p, func(*int) {
	atomic.AddUint32(&finalized, 1)
	})
	m.Store(p, struct{}{})
	m.Delete(p)
	runtime.GC()
	}
	}

	func TestMapRangeNestedCall(t *testing.T) { // Issue 46399
	var m sync.Map
	for i, v := range [3]string{"hello", "world", "Go"} {
	m.Store(i, v)
	}
	m.Range(func(key, value any) bool {
	m.Range(func(key, value any) bool {
	// We should be able to load the key offered in the Range callback,
	// because there are no concurrent Delete involved in this tested map.
	if v, ok := m.Load(key); !ok \|\| !reflect.DeepEqual(v, value) {
	t.Fatalf("Nested Range loads unexpected value, got %+v want %+v", v, value)
	}

	// We didn't keep 42 and a value into the map before, if somehow we loaded
	// a value from such a key, meaning there must be an internal bug regarding
	// nested range in the Map.
	if _, loaded := m.LoadOrStore(42, "dummy"); loaded {
	t.Fatalf("Nested Range loads unexpected value, want store a new value")
	}

	// Try to Store then LoadAndDelete the corresponding value with the key
	// 42 to the Map. In this case, the key 42 and associated value should be
	// removed from the Map. Therefore any future range won't observe key 42
	// as we checked in above.
	val := "sync.Map"
	m.Store(42, val)
	if v, loaded := m.LoadAndDelete(42); !loaded \|\| !reflect.DeepEqual(v, val) {
	t.Fatalf("Nested Range loads unexpected value, got %v, want %v", v, val)
	}
	return true
	})

	// Remove key from Map on-the-fly.
	m.Delete(key)
	return true
	})

	// After a Range of Delete, all keys should be removed and any
	// further Range won't invoke the callback. Hence length remains 0.
	length := 0
	m.Range(func(key, value any) bool {
	length++
	return true
	})

	if length != 0 {
	t.Fatalf("Unexpected sync.Map size, got %v want %v", length, 0)
	}
	}