The key thing to understand is that in Rust, references are considered unique types. This means that &T is a separate type from T.

So, for #1, it is not saying that T implements Copy, it is saying that regardless of what T is, &T implements Copy. This is because, by definition, it is always valid to copy a shared reference, even if T itself is not Copy.

Part of the reason this is confusing is that traits often include references in their function signatures; and in particular, Clone::clone has the signature fn clone(&self) -> Self. So when T implements clone, it has a method that takes &T and returns T. But even though the signature takes &T, the type that implements Clone is T itself. (&T always implements Clone as well, just as it always implements Copy, but as with Copy, this is independent from whether T itself implements Clone. See for example the error message you get when explicitly cloning a shared reference: https://play.rust-lang.org/?version=stable&mode=debug&edition=2021&gist=a1b80cc83570321868c4ad55ee3353dc)

Since Copy is a marker trait, it doesn’t have any associated methods making it explicit that Copy affects how &T can be used. However, Copy requires the type to implement Clone (even though you can implement Clone in terms of Copy) and implies that T can always be automatically created from &T without an explicit call to T::clone, so you can think of the “signature” for Copy as matching that of Clone, even though there’s no actual copy method.

For #2, I recommend thinking in terms of explicit types. Adding annotations, you get:

let mut x: Box = Box::new(42); *x = 84_i32;

The type of x is Box. You cannot assign an i32 to a Box; they’re different types! But the type of *x is i32, and thus you can assign 84 to it.

The trait used to make Box behave this way is DerefMut, which explicitly makes *x assignable: https://doc.rust-lang.org/std/ops/trait.DerefMut.html