programmieren-in-rust/aufgaben/sheet11/sol1/loop.rs

use std::cell::RefCell;
use std::rc::Rc;

/// A helper type to visualise drops on the terminal. Isn't it cute? :3
struct HappyDrop;

impl Drop for HappyDrop {
    fn drop(&mut self) {
        println!("❤ I have been dropped! ╰( ◕ ᗜ ◕ )╯");
    }
}

/// We need another wrapper type to avoid having infinitely nested types. This
/// is also useful to include the drop-indicator.
struct Node {
    /// Drop-indicator. This could also be sensitive data that requires
    /// its destructor to be executed (you shouldn't rely on that for safety
    /// purposes!).
    ///
    /// Silence warnings, because the `drop()` *is* used.
    #[allow(dead_code)]
    happy: HappyDrop,
    /// An optional shared reference to another node, which can mutated through
    /// an immutable reference.
    rc: RefCell<Option<Rc<Node>>>,
}

fn main() {
    // We create our first object, without a reference.
    let one = Rc::new(Node {
        happy: HappyDrop,
        rc: RefCell::new(None),
    });

    // This is the second node which now also owns the first node.
    let two = Rc::new(Node {
        happy: HappyDrop,
        // `two` is owner of `one` now. Note that we `clone()` the Rc around
        // one to create a new owner, instead of moving the ownership from the
        // stack frame into two. After this, `two` and the `main` stackframe
        // are owner of `one`.
        rc: RefCell::new(Some(one.clone())),
    });

    // This next line closes the cycle. We can access `one` here, because our
    // stackframe is owner too! We use the RefCell to mutate the optional
    // reference to another node and make `one` owner of `two`.
    *one.rc.borrow_mut() = Some(two);
}
Add solution for sheet11 2017-01-31 16:10:59 +01:00			`use std::cell::RefCell;`
			`use std::rc::Rc;`

			`/// A helper type to visualise drops on the terminal. Isn't it cute? :3`
			`struct HappyDrop;`

			`impl Drop for HappyDrop {`
			`fn drop(&mut self) {`
			`println!("❤ I have been dropped! ╰( ◕ ᗜ ◕ )╯");`
			`}`
			`}`

			`/// We need another wrapper type to avoid having infinitely nested types. This`
			`/// is also useful to include the drop-indicator.`
			`struct Node {`
			`/// Drop-indicator. This could also be sensitive data that requires`
			`/// its destructor to be executed (you shouldn't rely on that for safety`
			`/// purposes!).`
			`///`
			/// Silence warnings, because the `drop()` is used.
			`#[allow(dead_code)]`
			`happy: HappyDrop,`
			`/// An optional shared reference to another node, which can mutated through`
			`/// an immutable reference.`
			`rc: RefCell<Option<Rc<Node>>>,`
			`}`

			`fn main() {`
			`// We create our first object, without a reference.`
			`let one = Rc::new(Node {`
			`happy: HappyDrop,`
			`rc: RefCell::new(None),`
			`});`

			`// This is the second node which now also owns the first node.`
			`let two = Rc::new(Node {`
			`happy: HappyDrop,`
			// `two` is owner of `one` now. Note that we `clone()` the Rc around
			`// one to create a new owner, instead of moving the ownership from the`
			// stack frame into two. After this, `two` and the `main` stackframe
			// are owner of `one`.
			`rc: RefCell::new(Some(one.clone())),`
			`});`

			// This next line closes the cycle. We can access `one` here, because our
			`// stackframe is owner too! We use the RefCell to mutate the optional`
			// reference to another node and make `one` owner of `two`.
			`*one.rc.borrow_mut() = Some(two);`
			`}`