// This exercise explores the `Cow` (Clone-On-Write) smart pointer. It can // enclose and provide immutable access to borrowed data and clone the data // lazily when mutation or ownership is required. The type is designed to work // with general borrowed data via the `Borrow` trait. use std::borrow::Cow; fn abs_all(input: &mut Cow<[i32]>) { for ind in 0..input.len() { let value = input[ind]; if value < 0 { // Clones into a vector if not already owned. input.to_mut()[ind] = -value; } } } fn main() { // You can optionally experiment here. } #[cfg(test)] mod tests { use super::*; #[test] fn reference_mutation() { // Clone occurs because `input` needs to be mutated. let vec = vec![-1, 0, 1]; let mut input = Cow::from(&vec); abs_all(&mut input); assert!(matches!(input, Cow::Owned(_))); } #[test] fn reference_no_mutation() { // No clone occurs because `input` doesn't need to be mutated. let vec = vec![0, 1, 2]; let mut input = Cow::from(&vec); abs_all(&mut input); // TODO: Replace `todo!()` with `Cow::Owned(_)` or `Cow::Borrowed(_)`. assert!(matches!(input, todo!())); } #[test] fn owned_no_mutation() { // We can also pass `vec` without `&` so `Cow` owns it directly. In this // case, no mutation occurs and thus also no clone. But the result is // still owned because it was never borrowed or mutated. let vec = vec![0, 1, 2]; let mut input = Cow::from(vec); abs_all(&mut input); // TODO: Replace `todo!()` with `Cow::Owned(_)` or `Cow::Borrowed(_)`. assert!(matches!(input, todo!())); } #[test] fn owned_mutation() { // Of course this is also the case if a mutation does occur. In this // case, the call to `to_mut()` in the `abs_all` function returns a // reference to the same data as before. let vec = vec![-1, 0, 1]; let mut input = Cow::from(vec); abs_all(&mut input); // TODO: Replace `todo!()` with `Cow::Owned(_)` or `Cow::Borrowed(_)`. assert!(matches!(input, todo!())); } }