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/// An iterator that produces only the `T` values as long as the /// inner iterator produces `Ok(T)`. /// /// Used by [`process_results`](../fn.process_results.html), see its docs /// for more information. #[must_use = "iterator adaptors are lazy and do nothing unless consumed"] #[derive(Debug)] pub struct ProcessResults<'a, I, E: 'a> { error: &'a mut Result<(), E>, iter: I, } impl<'a, I, T, E> Iterator for ProcessResults<'a, I, E> where I: Iterator<Item = Result<T, E>> { type Item = T; fn next(&mut self) -> Option<Self::Item> { match self.iter.next() { Some(Ok(x)) => Some(x), Some(Err(e)) => { *self.error = Err(e); None } None => None, } } fn size_hint(&self) -> (usize, Option<usize>) { let (_, hi) = self.iter.size_hint(); (0, hi) } } /// “Lift” a function of the values of an iterator so that it can process /// an iterator of `Result` values instead. /// /// `iterable` is an iterator or iterable with `Result<T, E>` elements, where /// `T` is the value type and `E` the error type. /// /// `processor` is a closure that receives an adapted version of the iterable /// as the only argument — the adapted iterator produces elements of type `T`, /// as long as the original iterator produces `Ok` values. /// /// If the original iterable produces an error at any point, the adapted /// iterator ends and the `process_results` function will return the /// error iself. /// /// Otherwise, the return value from the closure is returned wrapped /// inside `Ok`. /// /// # Example /// /// ``` /// use itertools::process_results; /// /// type R = Result<i32, &'static str>; /// /// let first_values: Vec<R> = vec![Ok(1), Ok(0), Ok(3)]; /// let second_values: Vec<R> = vec![Ok(2), Ok(1), Err("overflow")]; /// /// // “Lift” the iterator .max() method to work on the values in Results using process_results /// /// let first_max = process_results(first_values, |iter| iter.max().unwrap_or(0)); /// let second_max = process_results(second_values, |iter| iter.max().unwrap_or(0)); /// /// assert_eq!(first_max, Ok(3)); /// assert!(second_max.is_err()); /// ``` pub fn process_results<I, F, T, E, R>(iterable: I, processor: F) -> Result<R, E> where I: IntoIterator<Item = Result<T, E>>, F: FnOnce(ProcessResults<I::IntoIter, E>) -> R { let iter = iterable.into_iter(); let mut error = Ok(()); let result = processor(ProcessResults { error: &mut error, iter }); error.map(|_| result) }