golang 做了个mutex与atomic性能测试
func BenchmarkMutex(b *testing.B) { var number int lock := sync.Mutex{} for i:=0; i< b.N;i++{ go func() { defer lock.Unlock() lock.Lock() number++ }() } } func BenchmarkAtomic(b *testing.B) { var number int32 for i:=0; i< b.N;i++{ go func() { atomic.AddInt32(&number, 1) }() } }
用两个函数做性能测试 benchmarkMutex与benchmarkAtomic 来比较互斥锁的差异
$ go test -v -cpu 1,2,4 -benchmem -bench=. goos: darwin goarch: amd64 pkg: puzzlers/article21/q3 BenchmarkMutex 1000000 2949 ns/op 424 B/op 0 allocs/op BenchmarkMutex-2 5000000 336 ns/op 22 B/op 0 allocs/op BenchmarkMutex-4 10000000 205 ns/op 0 B/op 0 allocs/op BenchmarkAtomic 2000000 1745 ns/op 156 B/op 0 allocs/op BenchmarkAtomic-2 10000000 176 ns/op 0 B/op 0 allocs/op BenchmarkAtomic-4 10000000 225 ns/op 0 B/op 0 allocs/op PASS ok puzzlers/article21/q3 26.179s
我们发现原子锁的性能高于互斥锁 不管从内存消耗与CPU运行 都比互斥锁要好