Expand description

“Fallible” iterators.

The iterator APIs in the Rust standard library do not support iteration that can fail in a first class manner. These iterators are typically modeled as iterating over Result<T, E> values; for example, the Lines iterator returns io::Result<String>s. When simply iterating over these types, the value being iterated over must be unwrapped in some way before it can be used:

for line in reader.lines() {
    let line = line?;
    // work with line
}

In addition, many of the additional methods on the Iterator trait will not behave properly in the presence of errors when working with these kinds of iterators. For example, if one wanted to count the number of lines of text in a Reader, this might be a way to go about it:

let count = reader.lines().count();

This will return the proper value when the reader operates successfully, but if it encounters an IO error, the result will either be slightly higher than expected if the error is transient, or it may run forever if the error is returned repeatedly!

In contrast, a fallible iterator is built around the concept that a call to next can fail. The trait has an additional Error associated type in addition to the Item type, and next returns Result<Option<Self::Item>, Self::Error> rather than Option<Self::Item>. Methods like count return Results as well.

This does mean that fallible iterators are incompatible with Rust’s for loop syntax, but while let loops offer a similar level of ergonomics:

while let Some(item) = iter.next()? {
    // work with item
}

Fallible closure arguments

Like Iterator, many FallibleIterator methods take closures as arguments. These use the same signatures as their Iterator counterparts, except that FallibleIterator expects the closures to be fallible: they return Result<T, Self::Error> instead of simply T.

For example, the standard library’s Iterator::filter adapter method filters the underlying iterator according to a predicate provided by the user, whose return type is bool. In FallibleIterator::filter, however, the predicate returns Result<bool, Self::Error>:

let numbers = convert("100\n200\nfern\n400".lines().map(Ok::<&str, Box<Error>>));
let big_numbers = numbers.filter(|n| Ok(u64::from_str(n)? > 100));
assert!(big_numbers.count().is_err());

Structs

An iterator which yields the elements of one iterator followed by another.
An iterator which clones the elements of the underlying iterator.
A fallible iterator that wraps a normal iterator over Results.
An iterator that yields the iteration count as well as the values of the underlying iterator.
An iterator which uses a fallible predicate to determine which values of the underlying iterator should be yielded.
An iterator which both filters and maps the values of the underlying iterator.
An iterator that yields Ok(None) forever after the underlying iterator yields Ok(None) once.
A normal (non-fallible) iterator which wraps a fallible iterator.
An iterator which applies a fallible transform to the elements of the underlying iterator.
An iterator which applies a transform to the errors of the underlying iterator.
An iterator which can look at the next element without consuming it.
An iterator which yields elements of the underlying iterator in reverse order.
An iterator which applies a stateful closure.
An iterator which skips initial elements.
An iterator which skips initial elements based on a predicate.
An iterator which steps through the elements of the underlying iterator by a certain amount.
An iterator which yields a limited number of elements from the underlying iterator.
An iterator which yields elements based on a predicate.
An iterator that yields pairs of this iterator’s and another iterator’s values.

Traits

A fallible iterator able to yield elements from both ends.
An Iterator-like trait that allows for calculation of items to fail.
Conversion from a fallible iterator.
Conversion into a FallibleIterator.

Functions

Converts an Iterator<Item = Result<T, E>> into a FallibleIterator<Item = T, Error = E>.