// from_str.rs // This is similar to from_into.rs, but this time we'll implement `FromStr` // and return errors instead of falling back to a default value. // Additionally, upon implementing FromStr, you can use the `parse` method // on strings to generate an object of the implementor type. // You can read more about it at https://doc.rust-lang.org/std/str/trait.FromStr.html // Execute `rustlings hint from_str` or use the `hint` watch subcommand for a hint. use std::num::ParseIntError; use std::str::FromStr; #[derive(Debug, PartialEq)] struct Person { name: String, age: usize, } // We will use this error type for the `FromStr` implementation. #[derive(Debug, PartialEq)] enum ParsePersonError { // Empty input string Empty, // Incorrect number of fields BadLen, // Empty name field NoName, // Wrapped error from parse::() ParseInt(ParseIntError), } // Steps: // 1. If the length of the provided string is 0, an error should be returned // 2. Split the given string on the commas present in it // 3. Only 2 elements should be returned from the split, otherwise return an error // 4. Extract the first element from the split operation and use it as the name // 5. Extract the other element from the split operation and parse it into a `usize` as the age // with something like `"4".parse::()` // 6. If while extracting the name and the age something goes wrong, an error should be returned // If everything goes well, then return a Result of a Person object // // As an aside: `Box` implements `From<&'_ str>`. This means that if you want to return a // string error message, you can do so via just using return `Err("my error message".into())`. impl FromStr for Person { type Err = ParsePersonError; fn from_str(s: &str) -> Result { let vec: Vec<&str> = s.split(",").collect(); let name = vec[0].trim(); let age = vec[vec.len() - 1].parse::(); if vec.len() == 2 && name.len() > 0 && age.is_ok() { Ok(Person { name: name.to_string(), age: age.unwrap() }) } else { if s.trim().len() == 0 { Err(ParsePersonError::Empty) } else if vec.len() != 2 { Err(ParsePersonError::BadLen) } else if name.len() == 0 { Err(ParsePersonError::NoName) } else { Err(ParsePersonError::ParseInt(age.unwrap_err())) } } } } fn main() { let p = "Mark,20".parse::().unwrap(); println!("{:?}", p); } #[cfg(test)] mod tests { use super::*; #[test] fn empty_input() { assert_eq!("".parse::(), Err(ParsePersonError::Empty)); } #[test] fn good_input() { let p = "John,32".parse::(); assert!(p.is_ok()); let p = p.unwrap(); assert_eq!(p.name, "John"); assert_eq!(p.age, 32); } #[test] fn missing_age() { assert!(matches!( "John,".parse::(), Err(ParsePersonError::ParseInt(_)) )); } #[test] fn invalid_age() { assert!(matches!( "John,twenty".parse::(), Err(ParsePersonError::ParseInt(_)) )); } #[test] fn missing_comma_and_age() { assert_eq!("John".parse::(), Err(ParsePersonError::BadLen)); } #[test] fn missing_name() { assert_eq!(",1".parse::(), Err(ParsePersonError::NoName)); } #[test] fn missing_name_and_age() { assert!(matches!( ",".parse::(), Err(ParsePersonError::NoName | ParsePersonError::ParseInt(_)) )); } #[test] fn missing_name_and_invalid_age() { assert!(matches!( ",one".parse::(), Err(ParsePersonError::NoName | ParsePersonError::ParseInt(_)) )); } #[test] fn trailing_comma() { assert_eq!("John,32,".parse::(), Err(ParsePersonError::BadLen)); } #[test] fn trailing_comma_and_some_string() { assert_eq!( "John,32,man".parse::(), Err(ParsePersonError::BadLen) ); } }