22

Is assigning a pointer atomic in Go?

Do I need to assign a pointer in a lock? Suppose I just want to assign the pointer to nil, and would like other threads to be able to see it. I know in Java we can use volatile for this, but there is no volatile in Go.

2
  • You might find this thread interesting.
    – kostix
    Jan 30 '14 at 15:40
  • 1
    You might also find reading the "Go memory model" document amusing--it's what defines the requirements for Go implementations. AFAIK, it does not tell anything about atomicity of load/store operations of primitive types but only speaks about observable ordering of them.
    – kostix
    Jan 30 '14 at 15:59
18

The only things which are guaranteed to be atomic in go are the operations in sync.atomic.

So if you want to be certain you'll either need to take a lock, eg sync.Mutex or use one of the atomic primitives. I don't recommend using the atomic primitives though as you'll have to use them everywhere you use the pointer and they are difficult to get right.

Using the mutex is OK go style - you could define a function to return the current pointer with locking very easily, eg something like

import "sync"

var secretPointer *int
var pointerLock sync.Mutex

func CurrentPointer() *int {
    pointerLock.Lock()
    defer pointerLock.Unlock()
    return secretPointer
}

func SetPointer(p *int) {
    pointerLock.Lock()
    secretPointer = p
    pointerLock.Unlock()
}

These functions return a copy of the pointer to their clients which will stay constant even if the master pointer is changed. This may or may not be acceptable depending on how time critical your requirement is. It should be enough to avoid any undefined behaviour - the garbage collector will ensure that the pointers remain valid at all times even if the memory pointed to is no longer used by your program.

An alternative approach would be to only do the pointer access from one go routine and use channels to command that go routine into doing things. That would be considered more idiomatic go, but may not suit your application exactly.

Update

Here is an example showing how to use atomic.SetPointer. It is rather ugly due to the use of unsafe.Pointer. However unsafe.Pointer casts compile to nothing so the runtime cost is small.

import (
    "fmt"
    "sync/atomic"
    "unsafe"
)

type Struct struct {
    p unsafe.Pointer // some pointer
}

func main() {
    data := 1

    info := Struct{p: unsafe.Pointer(&data)}

    fmt.Printf("info is %d\n", *(*int)(info.p))

    otherData := 2

    atomic.StorePointer(&info.p, unsafe.Pointer(&otherData))

    fmt.Printf("info is %d\n", *(*int)(info.p))

}
5
  • I did look at the atomic package, and didn't see a method for atomic storing pointer to a struct. The method StorePointer doesn't look like the right one. func StorePointer(addr *unsafe.Pointer, val unsafe.Pointer)
    – Koda
    Jan 30 '14 at 8:50
  • 1
    Have updated the answer with a StorePointer example. Jan 30 '14 at 10:55
  • 3
    @NickCraig-Wood When using atomic.StorePointer, is it necessary to use atomic.ReadPointer in order to read it or is a regular non-atomic read okay? The store barrier used in atomic.StorePointer should block concurrent reads, so it sounds useless to me using atomic.ReadPointer in that case. Is that right? Jun 21 '19 at 12:23
  • Are you sure the first example would work in broader context: the thread doing SetPointer would presumably need to populate the pointed-to value before publishing the new pointer value. I didn't see anything in the memory model that establishes that the write to *secretPointer happens before the write to secretPointer, from the reader thread's point of view.
    – Brendan
    Nov 29 '19 at 7:58
  • On further meditation: with the mutex the read of secretPointer happens after the write by virtue of the mutex rules. The write of *secretPointer happens before the write of secretPointer by virtue of intra-goroutine program order. Those are enough to make it work.
    – Brendan
    Nov 29 '19 at 10:54
6

Since the spec doesn't specify you should assume it is not. Even if it is currently atomic it's possible that it could change without ever violating the spec.

2

In addition to Nick's answer, since Go 1.4 there is atomic.Value type. Its Store(interface) and Load() interface methods take care of the unsafe.Pointer conversion.

Simple example:

package main

import (
    "sync/atomic"
)

type stats struct{}

type myType struct {
    stats atomic.Value
}

func main() {
    var t myType
    
    s := new(stats)
    
    t.stats.Store(s)
    
    s = t.stats.Load().(*stats)
}

Or a more extended example from the documentation on the Go playground.

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