1

In the code here

trait Foo {
    type Output;
    fn foo(self) -> Self::Output;
}

impl<'a> Foo for &'a () {
    type Output = &'a ();
    fn foo(self) -> Self::Output {
        self
    }
}

fn func<F: Foo>(f: F) -> F::Output {
    f.foo()
}

fn func2<'a>(f: &'a ()) -> &'a () {
    func::<&'a ()>(f)
}

fn has_hrl<F: Fn(&()) -> &()>(f: F) {}

fn main() {
    //has_hrl(func); // FAILS
    has_hrl(func2);
    has_hrl(|x| func(x));
}

We would like to do has_hrl(func), but Rust only accepts the closure has_hrl(|x| func(x)). Why is that? Because it works with concrete types like in func2, but not with generic types.

|improve this question
  • This would work if you declared has_hrl like fn has_hrl<'a, F: Fn(&'a ()) -> &'a ()>(_: F) {}. My power level is insufficient to explain why the lifetime needs to be explicit, though. – ljedrz Sep 18 '16 at 16:56
7

In this expression:

has_hrl(func)

The compiler is forced to pick one specific instance of func. func is generic over F: Foo, and for all 'a, &'a () implements Foo, but the compiler can only choose one particular 'a to instantiate func, because a type variable cannot represent a multitude of types. Therefore, func::<&'a ()> does not implement for<'a> Fn(&'a ()) -> &'a (), it only implements Fn(&'x ()) -> &'x () for one specific lifetime 'x.

This would work if you declared has_hrl like fn has_hrl<'a, F: Fn(&'a ()) -> &'a ()>(_: F) {}. My power level is insufficient to explain why the lifetime needs to be explicit, though. – ljedrz

That's because the original declaration has an implied higher-ranked lifetime bound (the bound is equivalent to F: for<'a> Fn(&'a ()) -> &'a ()), which means that F must implement Fn(&'a ()) -> &'a () for all lifetimes 'a. Your version only requires F to implement Fn(&'a ()) -> &'a () for one concrete lifetime. You'll also find that this version doesn't work if has_hrl tries to call the closure with a lifetime that is local to the has_hrl function, because the caller cannot possibly pass that lifetime as a parameter (which is why higher-ranked lifetime bounds were introduced).

|improve this answer
  • I just tried splitting the statement has_hrl(|x| func(x)); into 2 statements: let f = |x| func(x); has_hrl(f); and the same error shows up. Somehow appearing as an argument is handled differently from a variable binding (a binding should be pinned to a fully concrete type). So I am guessing even Higher Ranked Lifetimes are not yet well-captured by Rust's current type system (and uses some kinda tricks behind the scenes)? – John Sep 18 '16 at 19:13
  • I understand that it has higher ranked lifetimes, but I still don't understand why it doesn't work, it seems like this is something that should work. – iopq Sep 19 '16 at 10:36
  • @iopq: You're not alone... – Francis Gagné Sep 19 '16 at 22:21
  • Your first part isn't quite correct. The compiler can instantiate a single func::<&'a ()> for all 'a; it's doing exactly this inside func2. That is, rustc instantiates exactly one copy of func2 which means there must exist a single func::<&'a ()> valid for all 'a. Unfortunately, rustc doesn't appear to expose this fact in the type system. – Steven Sep 21 '16 at 16:24
  • @Steven: It's true that there is a single func::<&'a ()> for all 'a, as lifetime parameters are erased, unlike type parameters. This may be why we have higher-rank lifetimes but not higher-rank types (e.g. for<T> Fn(T)), which might be more complex to implement. – Francis Gagné Sep 21 '16 at 17:55

Your Answer

By clicking "Post Your Answer", you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.