// Let's define a simple model to track Rustlings' exercise progress. Progress // will be modelled using a hash map. The name of the exercise is the key and // the progress is the value. Two counting functions were created to count the // number of exercises with a given progress. Recreate this counting // functionality using iterators. Try to not use imperative loops (for/while). use std::collections::HashMap; #[derive(Clone, Copy, PartialEq, Eq)] enum Progress { None, Some, Complete, } fn count_for(map: &HashMap, value: Progress) -> usize { let mut count = 0; for val in map.values() { if *val == value { count += 1; } } count } // TODO: Implement the functionality of `count_for` but with an iterator instead // of a `for` loop. fn count_iterator(map: &HashMap, value: Progress) -> usize { // `map` is a hash map with `String` keys and `Progress` values. // map = { "variables1": Complete, "from_str": None, … } } fn count_collection_for(collection: &[HashMap], value: Progress) -> usize { let mut count = 0; for map in collection { for val in map.values() { if *val == value { count += 1; } } } count } // TODO: Implement the functionality of `count_collection_for` but with an // iterator instead of a `for` loop. fn count_collection_iterator(collection: &[HashMap], value: Progress) -> usize { // `collection` is a slice of hash maps. // collection = [{ "variables1": Complete, "from_str": None, … }, // { "variables2": Complete, … }, … ] } fn main() { // You can optionally experiment here. } #[cfg(test)] mod tests { use super::*; fn get_map() -> HashMap { use Progress::*; let mut map = HashMap::new(); map.insert(String::from("variables1"), Complete); map.insert(String::from("functions1"), Complete); map.insert(String::from("hashmap1"), Complete); map.insert(String::from("arc1"), Some); map.insert(String::from("as_ref_mut"), None); map.insert(String::from("from_str"), None); map } fn get_vec_map() -> Vec> { use Progress::*; let map = get_map(); let mut other = HashMap::new(); other.insert(String::from("variables2"), Complete); other.insert(String::from("functions2"), Complete); other.insert(String::from("if1"), Complete); other.insert(String::from("from_into"), None); other.insert(String::from("try_from_into"), None); vec![map, other] } #[test] fn count_complete() { let map = get_map(); assert_eq!(count_iterator(&map, Progress::Complete), 3); } #[test] fn count_some() { let map = get_map(); assert_eq!(count_iterator(&map, Progress::Some), 1); } #[test] fn count_none() { let map = get_map(); assert_eq!(count_iterator(&map, Progress::None), 2); } #[test] fn count_complete_equals_for() { let map = get_map(); let progress_states = [Progress::Complete, Progress::Some, Progress::None]; for progress_state in progress_states { assert_eq!( count_for(&map, progress_state), count_iterator(&map, progress_state), ); } } #[test] fn count_collection_complete() { let collection = get_vec_map(); assert_eq!( count_collection_iterator(&collection, Progress::Complete), 6, ); } #[test] fn count_collection_some() { let collection = get_vec_map(); assert_eq!(count_collection_iterator(&collection, Progress::Some), 1); } #[test] fn count_collection_none() { let collection = get_vec_map(); assert_eq!(count_collection_iterator(&collection, Progress::None), 4); } #[test] fn count_collection_equals_for() { let collection = get_vec_map(); let progress_states = [Progress::Complete, Progress::Some, Progress::None]; for progress_state in progress_states { assert_eq!( count_collection_for(&collection, progress_state), count_collection_iterator(&collection, progress_state), ); } } }