93

I'm familiar with the fact that, in Go, interfaces define functionality, rather than data. You put a set of methods into an interface, but you are unable to specify any fields that would be required on anything that implements that interface.

For example:

// Interface
type Giver interface {
    Give() int64
}

// One implementation
type FiveGiver struct {}

func (fg *FiveGiver) Give() int64 {
    return 5
}

// Another implementation
type VarGiver struct {
    number int64
}

func (vg *VarGiver) Give() int64 {
    return vg.number
}

Now we can use the interface and its implementations:

// A function that uses the interface
func GetSomething(aGiver Giver) {
    fmt.Println("The Giver gives: ", aGiver.Give())
}

// Bring it all together
func main() {
    fg := &FiveGiver{}
    vg := &VarGiver{3}
    GetSomething(fg)
    GetSomething(vg)
}

/*
Resulting output:
5
3
*/

Now, what you can't do is something like this:

type Person interface {
    Name string
    Age int64
}

type Bob struct implements Person { // Not Go syntax!
    ...
}

func PrintName(aPerson Person) {
    fmt.Println("Person's name is: ", aPerson.Name)
}

func main() {
    b := &Bob{"Bob", 23}
    PrintName(b)
}

However, after playing around with interfaces and embedded structs, I've discovered a way to do this, after a fashion:

type PersonProvider interface {
    GetPerson() *Person
}

type Person struct {
    Name string
    Age  int64
}

func (p *Person) GetPerson() *Person {
    return p
}

type Bob struct {
    FavoriteNumber int64
    Person
}

Because of the embedded struct, Bob has everything Person has. It also implements the PersonProvider interface, so we can pass Bob into functions that are designed to use that interface.

func DoBirthday(pp PersonProvider) {
    pers := pp.GetPerson()
    pers.Age += 1
}

func SayHi(pp PersonProvider) {
    fmt.Printf("Hello, %v!\r", pp.GetPerson().Name)
}

func main() {
    b := &Bob{
        5,
        Person{"Bob", 23},
    }
    DoBirthday(b)
    SayHi(b)
    fmt.Printf("You're %v years old now!", b.Age)
}

Here is a Go Playground that demonstrates the above code.

Using this method, I can make an interface that defines data rather than behavior, and which can be implemented by any struct just by embedding that data. You can define functions that explicitly interact with that embedded data and are unaware of the nature of the outer struct. And everything is checked at compile time! (The only way you could mess up, that I can see, would be embedding the interface PersonProvider in Bob, rather than a concrete Person. It would compile and fail at runtime.)

Now, here's my question: is this a neat trick, or should I be doing it differently?

  • 2
    "I can make an interface that defines data rather than behavior". I would argue that you have a behaviour that returns data. – jmaloney Sep 24 '14 at 22:22
  • I'm gonna write an answer; I think it's fine if you need it and know the consequences, but there are consequences and I wouldn't do it all the time. – twotwotwo Sep 24 '14 at 22:22
  • @jmaloney I think you're right, if you wanted to look at it plainly. But overall, with the different pieces I've shown, the semantics become "this function accepts any struct that has a ___ in its composition". At least, that's what I intended. – Matt Mc Sep 25 '14 at 0:11
  • 1
    This isn't "answer" material. I got to your question by googling "interface as struct property golang". I found a similar approach by setting a struct that implements an interface as the property of another struct. Here's the playground, play.golang.org/p/KLzREXk9xo Thanks for giving me some ideas. – Dale Aug 1 '16 at 4:59
  • Isn't the embedded struct just composition? – Alexander Mills Dec 3 '18 at 0:32
51

It is definitely a neat trick, and works as long as you're cool giving access to those fields as part of your API. The alternative I'd consider on is keeping the embeddable struct/interface setup, but defining the interface in terms of getters and setters.

Hiding properties behind getters and setters gives you some extra flexibility to make backwards-compatible changes later. Say you someday want to change Person to store not just a single "name" field but first/middle/last/prefix; if you have methods Name() string and SetName(string), you can keep existing users of the Person interface happy while adding new finer-grained methods. Or you might want to be able to mark a database-backed object as "dirty" when it has unsaved changes; you can do that when data updates all go through SetFoo() methods.

So: with getters/setters, you can change struct fields while maintaining a compatible API, and add logic around property get/sets since no one can just do p.Name = "bob" without going through your code.

That flexibility is more relevant when your type does something more complicated. If you have a PersonCollection, it might be internally backed by an sql.Rows, a []*Person, a []uint of database IDs, or whatever. Using the right interface, you can save callers from caring which it is, the way io.Reader makes network connections and files look alike.

One specific thing: interfaces in Go have the peculiar property that you can implement one without importing the package that defines it; that can help you avoid cyclic imports. If your interface returns a *Person, instead of just strings or whatever, all PersonProviders have to import the package where Person is defined. That may be fine or even inevitable; it's just a consequence to know about.

All that said, there's no Go convention that you have to hide all your data. (This is a welcome difference from, say, C++.) The stdlib does things like let you initialize an http.Server with your config and promises that a zero bytes.Buffer is usable. It's fine to do your own stuff like that, and, indeed, I don't think you have to do premature abstraction if the more concrete, data-exposing version works. It's just about being aware of the tradeoffs.

  • Reading over, my answer sounded really prescriptive because I was almost only giving the downsides. Unlike C++, Go has no dogma against exposing data if it works for you; tried to edit to emphasize that more. – twotwotwo Sep 25 '14 at 0:47
  • One additional thing: the embedding approach is a bit more like inheritance, right? You get any fields and methods that the embedded struct has, and you can use its interface so that any superstruct will qualify, without re-implementing sets of interfaces. – Matt Mc Sep 26 '14 at 2:22
  • Yeah--a lot like virtual inheritance in other langs. You can use embedding to implement an interface whether it's defined in terms of getters and setters or a pointer to the data (or, a third option for readonly access to tiny structs, a copy of the struct). – twotwotwo Sep 26 '14 at 4:14

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