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.

  • 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
up vote 7 down vote accepted

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).

  • 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

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