How does for<> syntax differ from a regular lifetime bound?
Solution 1:
for<>
syntax is called higher-ranked trait bound (HRTB), and it was indeed introduced mostly because of closures.
In short, the difference between foo
and bar
is that in foo()
the lifetime for the internal usize
reference is provided by the caller of the function, while in bar()
the same lifetime is provided by the function itself. And this distinction is very important for the implementation of foo
/bar
.
However, in this particular case, when Trait
has no methods which use the type parameter, this distinction is pointless, so let's imagine that Trait
looks like this:
trait Trait<T> {
fn do_something(&self, value: T);
}
Remember, lifetime parameters are very similar to generic type parameters. When you use a generic function, you always specify all of its type parameters, providing concrete types, and the compiler monomorphizes the function. Same thing goes with lifetime parameters: when you call a function which have a lifetime parameter, you specify the lifetime, albeit implicitly:
// imaginary explicit syntax
// also assume that there is TraitImpl::new::<T>() -> TraitImpl<T>,
// and TraitImpl<T>: Trait<T>
'a: {
foo::<'a>(Box::new(TraitImpl::new::<&'a usize>()));
}
And now there is a restriction on what foo()
can do with this value, that is, with which arguments it may call do_something()
. For example, this won't compile:
fn foo<'a>(b: Box<Trait<&'a usize>>) {
let x: usize = 10;
b.do_something(&x);
}
This won't compile because local variables have lifetimes which are strictly smaller than lifetimes specified by the lifetime parameters (I think it is clear why it is so), therefore you can't call b.do_something(&x)
because it requires its argument to have lifetime 'a
, which is strictly greater than that of x
.
However, you can do this with bar
:
fn bar(b: Box<for<'a> Trait<&'a usize>>) {
let x: usize = 10;
b.do_something(&x);
}
This works because now bar
can select the needed lifetime instead of the caller of bar
.
This does matter when you use closures which accept references. For example, suppose you want to write a filter()
method on Option<T>
:
impl<T> Option<T> {
fn filter<F>(self, f: F) -> Option<T> where F: FnOnce(&T) -> bool {
match self {
Some(value) => if f(&value) { Some(value) } else { None }
None => None
}
}
}
The closure here must accept a reference to T
because otherwise it would be impossible to return the value contained in the option (this is the same reasoning as with filter()
on iterators).
But what lifetime should &T
in FnOnce(&T) -> bool
have? Remember, we don't specify lifetimes in function signatures only because there is lifetime elision in place; actually the compiler inserts a lifetime parameter for each reference inside a function signature. There should be some lifetime associated with &T
in FnOnce(&T) -> bool
. So, the most "obvious" way to expand the signature above would be this:
fn filter<'a, F>(self, f: F) -> Option<T> where F: FnOnce(&'a T) -> bool
However, this is not going to work. As in the example with Trait
above, lifetime 'a
is strictly longer than the lifetime of any local variable in this function, including value
inside the match statement. Therefore, it is not possible to apply f
to &value
because of lifetime mismatch. The above function written with such signature won't compile.
On the other hand, if we expand the signature of filter()
like this (and this is actually how lifetime elision for closures works in Rust now):
fn filter<F>(self, f: F) -> Option<T> where F: for<'a> FnOnce(&'a T) -> bool
then calling f
with &value
as an argument is perfectly valid: we can choose the lifetime now, so using the lifetime of a local variable is absolutely fine. And that's why HRTBs are important: you won't be able to express a lot of useful patterns without them.
You can also read another explanation of HRTBs in Nomicon.