go语言自身提供了一种不使用锁来解决并发安全的行为那就是atomic.Value, 我们将指针指向golang 1.4 文档。
1.4中 在 Minor changes to the library 标记中新加了atomic.Value 类型,可以原子的加载和存储任意类型值,当我看到这个新提供的类型之后(1.4的时候)我很开心也很郁闷,因为官方包上写着
Package atomic provides low-level atomic memory primitives useful for implementing synchronization algorithms.
These functions require great care to be used correctly. Except for special, low-level applications, synchronization is better done with channels or the facilities of the sync package. Share memory by communicating; don't communicate by sharing memory.
所以我看完这句话也就继续在项目中使用锁和channel来处理并发安全,后来一个机会我看了下nsq的源码,发现里面大量的使用atomic.Value 于是在1.6之后我也开始在项目中大量的使用atomic.Value
package main
import (
"fmt"
"sync/atomic"
)
type Value struct {
Key string
Val interface{}
}
type Noaway struct {
Movies atomic.Value
Total atomic.Value
}
func NewNoaway() *Noaway {
n := new(Noaway)
n.Movies.Store(&Value{Key: "movie", Val: "Wolf Warrior 2"})
n.Total.Store("$2,539,306")
return n
}
func main() {
n := NewNoaway()
val := n.Movies.Load().(*Value)
total := n.Total.Load().(string)
fmt.Printf("Movies %v domestic total as of Aug. 27, 2017: %v \n", val.Val, total)
}
这个例子看起来很好,线程安全还没有锁,逻辑复杂的时候也不用使用defer了,我使用benchmark和锁对比一下看看是否是自己想要的结果:
package noaway_test
import (
"sync"
"sync/atomic"
"testing"
)
type manager struct {
sync.RWMutex
agents int
}
func BenchmarkManagerLock(b *testing.B) {
m := new(manager)
b.ReportAllocs()
b.RunParallel(func(pb *testing.PB) {
for pb.Next() {
m.Lock()
m.agents = 100
m.Unlock()
}
})
}
func BenchmarkManagerRLock(b *testing.B) {
m := manager{agents: 100}
b.ReportAllocs()
b.RunParallel(func(pb *testing.PB) {
for pb.Next() {
m.RLock()
_ = m.agents
m.RUnlock()
}
})
}
func BenchmarkManagerAtomicValueStore(b *testing.B) {
var managerVal atomic.Value
m := manager{agents: 100}
b.ReportAllocs()
b.RunParallel(func(pb *testing.PB) {
for pb.Next() {
managerVal.Store(m)
}
})
}
func BenchmarkManagerAtomicValueLoad(b *testing.B) {
var managerVal atomic.Value
managerVal.Store(&manager{agents: 100})
b.ReportAllocs()
b.RunParallel(func(pb *testing.PB) {
for pb.Next() {
_ = managerVal.Load().(*manager)
}
})
}
确实是自己想要的结果 ?,但是你在文档中会看到这样的注释
func (*Value) Load
func (v *Value) Load() (x interface{})
Load returns the value set by the most recent Store. It returns nil if there has been no call to Store for this Value.
func (*Value) Store
func (v *Value) Store(x interface{})
Store sets the value of the Value to x. All calls to Store for a given Value must use values of the same concrete type. Store of an inconsistent type panics, as does Store(nil).
事实证明我们在使用atomic的时候还是遵从官方的使用方式,以下是一个老外遇到的情况:
I’ve received a private report about poor encoding/gob performance on a 80-core machine. encoding/gob has a bunch of global mutexes. By removing just one of them, I’ve got 2x speedup on 16-core machine. If all mutexes are removed on the 80-core machine it can easily make 20x difference.
This kind of scalable synchronization algorithms inherently requires unsafe package today. This means that it is incompatible with appengine and other safe contexts. While it is not actually unsafe. Looks like a quite unfortunate situation to me. Today people use 80-code machines, tomorrow they will use 200-core machines. Mutexes don’t work there in any way, shape or form.
If Go wants to continue to be positioned as “the way to program modern multicore machines” (which I believe it was initially), then it must provide relevant means for that and its base libraries must not impose scalability bottlenecks.
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