// Using catch-all error types like `Box` isn't recommended for // library code where callers might want to make decisions based on the error // content instead of printing it out or propagating it further. Here, we define // a custom error type to make it possible for callers to decide what to do next // when our function returns an error. use std::num::ParseIntError; #[derive(PartialEq, Debug)] enum CreationError { Negative, Zero, } // A custom error type that we will be using in `PositiveNonzeroInteger::parse`. #[derive(PartialEq, Debug)] enum ParsePosNonzeroError { Creation(CreationError), ParseInt(ParseIntError), } impl ParsePosNonzeroError { fn from_creation(err: CreationError) -> Self { Self::Creation(err) } // TODO: Add another error conversion function here. // fn from_parse_int(???) -> Self { ??? } } #[derive(PartialEq, Debug)] struct PositiveNonzeroInteger(u64); impl PositiveNonzeroInteger { fn new(value: i64) -> Result { match value { x if x < 0 => Err(CreationError::Negative), 0 => Err(CreationError::Zero), x => Ok(Self(x as u64)), } } fn parse(s: &str) -> Result { // TODO: change this to return an appropriate error instead of panicking // when `parse()` returns an error. let x: i64 = s.parse().unwrap(); Self::new(x).map_err(ParsePosNonzeroError::from_creation) } } fn main() { // You can optionally experiment here. } #[cfg(test)] mod test { use super::*; #[test] fn test_parse_error() { assert!(matches!( PositiveNonzeroInteger::parse("not a number"), Err(ParsePosNonzeroError::ParseInt(_)), )); } #[test] fn test_negative() { assert_eq!( PositiveNonzeroInteger::parse("-555"), Err(ParsePosNonzeroError::Creation(CreationError::Negative)), ); } #[test] fn test_zero() { assert_eq!( PositiveNonzeroInteger::parse("0"), Err(ParsePosNonzeroError::Creation(CreationError::Zero)), ); } #[test] fn test_positive() { let x = PositiveNonzeroInteger::new(42).unwrap(); assert_eq!(x.0, 42); assert_eq!(PositiveNonzeroInteger::parse("42"), Ok(x)); } }