// box1.rs // // At compile time, Rust needs to know how much space a type takes up. This // becomes problematic for recursive types, where a value can have as part of // itself another value of the same type. To get around the issue, we can use a // `Box` - a smart pointer used to store data on the heap, which also allows us // to wrap a recursive type. // // The recursive type we're implementing in this exercise is the `cons list` - a // data structure frequently found in functional programming languages. Each // item in a cons list contains two elements: the value of the current item and // the next item. The last item is a value called `Nil`. // // Step 1: use a `Box` in the enum definition to make the code compile // Step 2: create both empty and non-empty cons lists by replacing `todo!()` // // Note: the tests should not be changed // // Execute `rustlings hint box1` or use the `hint` watch subcommand for a hint. #[derive(PartialEq, Debug)] pub enum List { Cons(i32, Box), Nil, } use crate::List::{Cons, Nil}; fn main() { println!("This is an empty cons list: {:?}", create_empty_list()); println!( "This is a non-empty cons list: {:?}", create_non_empty_list() ); } pub fn create_empty_list() -> List { return Nil; } pub fn create_non_empty_list() -> List { return Cons(2, Box::new(Cons(5, Box::new(Nil)))); } #[cfg(test)] mod tests { use super::*; #[test] fn test_create_empty_list() { assert_eq!(List::Nil, create_empty_list()) } #[test] fn test_create_non_empty_list() { assert_ne!(create_empty_list(), create_non_empty_list()) } }