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gmutex模块是基于atomic + channel实现的高级互斥锁模块,支持更丰富的互斥锁特性。
gmutex.Mutex互斥锁对象支持读写控制,互斥锁功能逻辑与标准库sync.RWMutex类似,可并发读但不可并发写。
互斥锁的设计细节,推荐阅读轻量级高清版的实现源码:https://github.com/gogf/gf/v2/blob/master/os/gmutex/gmutex.go
使用方式:
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import "github.com/gogf/gf/v2/os/gmutex" |
接口文档:
https://pkg.go.dev/github.com/gogf/gf/v2/os/gmutex
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type Mutex
func New() *Mutex
func (m *Mutex) IsLocked() bool
func (m *Mutex) IsRLocked() bool
func (m *Mutex) IsWLocked() bool
func (m *Mutex) Lock()
func (m *Mutex) LockFunc(f func())
func (m *Mutex) RLock()
func (m *Mutex) RLockFunc(f func())
func (m *Mutex) RUnlock()
func (m *Mutex) TryLock() bool
func (m *Mutex) TryLockFunc(f func()) bool
func (m *Mutex) TryRLock() bool
func (m *Mutex) TryRLockFunc(f func()) bool
func (m *Mutex) Unlock() |
- 该互斥锁模块最大的特点是支持
Try*方法以及*Func方法。 Try*方法用于实现尝试获得特定类型的锁,如果获得锁成功则立即返回true,否则立即返回false,不会阻塞等待,这对于需要使用非阻塞锁机制的业务逻辑非常实用。*Func方法使用闭包匿名函数的方式实现特定作用域的并发安全锁控制,这对于特定代码块的并发安全控制特别方便,由于内部使用了defer来释放锁,因此即使函数内部产生异常错误,也不会影响锁机制的安全性控制。
基准测试
gmutex.Mutex与标准库的sync.Mutex及sync.RWMutex的基准测试对比结果: gmutex_bench_test.go
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goos: linux goarch: amd64 pkg: github.com/gogf/gf/v2/os/gmutex Benchmark_Mutex_LockUnlock-4 50000000 31.5 ns/op Benchmark_RWMutex_LockUnlock-4 30000000 54.1 ns/op Benchmark_RWMutex_RLockRUnlock-4 50000000 27.9 ns/op Benchmark_GMutex_LockUnlock-4 50000000 27.2 ns/op Benchmark_GMutex_TryLock-4 100000000 16.7 ns/op Benchmark_GMutex_RLockRUnlock-4 50000000 38.0 ns/op Benchmark_GMutex_TryRLock-4 100000000 16.8 ns/op |
示例1,基本使用
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package main
import (
"time"
"github.com/gogf/gf/v2/os/glog"
"github.com/gogf/gf/v2/os/gmutex"
)
func main() {
mu := gmutex.New()
for i := 0; i < 10; i++ {
go func(n int) {
mu.Lock()
defer mu.Unlock()
glog.Println("Lock:", n)
time.Sleep(time.Second)
}(i)
}
for i := 0; i < 10; i++ {
go func(n int) {
mu.RLock()
defer mu.RUnlock()
glog.Println("RLock:", n)
time.Sleep(time.Second)
}(i)
}
time.Sleep(11 * time.Second)
} |
执行后,终端输出:
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2019-07-13 16:19:55.417 Lock: 0 2019-07-13 16:19:56.421 Lock: 1 2019-07-13 16:19:57.424 RLock: 0 2019-07-13 16:19:57.424 RLock: 4 2019-07-13 16:19:57.425 RLock: 8 2019-07-13 16:19:57.425 RLock: 2 2019-07-13 16:19:57.425 RLock: 7 2019-07-13 16:19:57.425 RLock: 5 2019-07-13 16:19:57.425 RLock: 9 2019-07-13 16:19:57.425 RLock: 1 2019-07-13 16:19:57.425 RLock: 6 2019-07-13 16:19:57.425 RLock: 3 2019-07-13 16:19:58.429 Lock: 3 2019-07-13 16:19:59.433 Lock: 4 2019-07-13 16:20:00.438 Lock: 5 2019-07-13 16:20:01.443 Lock: 6 2019-07-13 16:20:02.448 Lock: 7 2019-07-13 16:20:03.452 Lock: 8 2019-07-13 16:20:04.456 Lock: 9 2019-07-13 16:20:05.461 Lock: 2 |
这里使用glog打印的目的,是可以方便地看到打印输出的时间。可以看到,在第3秒的时候,读锁抢占到了机会,由于gmutex.Mutex对象支持并发读但不支持并发写,因此读锁抢占后迅速执行完毕;而写锁依旧保持每秒打印一条日志继续执行。
示例2,*Func使用
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package main
import (
"time"
"github.com/gogf/gf/v2/os/glog"
"github.com/gogf/gf/v2/os/gmutex"
)
func main() {
mu := gmutex.New()
go mu.LockFunc(func() {
glog.Println("lock func1")
time.Sleep(1 * time.Second)
})
time.Sleep(time.Millisecond)
go mu.LockFunc(func() {
glog.Println("lock func2")
})
time.Sleep(2 * time.Second)
} |
执行后,终端输出:
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2019-07-13 16:28:10.381 lock func1 2019-07-13 16:28:11.385 lock func2 |
可以看到,使用*Func方法实现特定作用域的锁控制非常方便。
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