The Problem
A trait that is generic over its container type has type specification
requirements - users of the trait must specify all of its generic types.
In the example below, the Contains trait allows the use of the generic
types A and B. The trait is then implemented for the Container type,
specifying i32 for A and B so that it can be used with fn difference().
Because Contains is generic, we are forced to explicitly state all of the
generic types for fn difference(). In practice, we want a way to express that
A and B are determined by the input C. As you will see in the next
section, associated types provide exactly that capability.
struct Container(i32, i32); // A trait which checks if 2 items are stored inside of container. // Also retrieves first or last value. trait Contains<A, B> { fn contains(&self, _: &A, _: &B) -> bool; // Explicitly requires `A` and `B`. fn first(&self) -> i32; // Doesn't explicitly require `A` or `B`. fn last(&self) -> i32; // Doesn't explicitly require `A` or `B`. } impl Contains<i32, i32> for Container { // True if the numbers stored are equal. fn contains(&self, number_1: &i32, number_2: &i32) -> bool { (&self.0 == number_1) && (&self.1 == number_2) } // Grab the first number. fn first(&self) -> i32 { self.0 } // Grab the last number. fn last(&self) -> i32 { self.1 } } // `C` contains `A` and `B`. In light of that, having to express `A` and // `B` again is a nuisance. fn difference<A, B, C>(container: &C) -> i32 where C: Contains<A, B> { container.last() - container.first() } fn main() { let number_1 = 3; let number_2 = 10; let container = Container(number_1, number_2); println!("Does container contain {} and {}: {}", &number_1, &number_2, container.contains(&number_1, &number_2)); println!("First number: {}", container.first()); println!("Last number: {}", container.last()); println!("The difference is: {}", difference(&container)); }