pub trait Itertools: Iterator {
Show 106 methods
fn interleave<J>(self, other: J) -> Interleave<Self, J::IntoIter>ⓘNotable traits for Interleave<I, J>impl<I, J> Iterator for Interleave<I, J> where
I: Iterator,
J: Iterator<Item = I::Item>, type Item = I::Item;
where
J: IntoIterator<Item = Self::Item>,
Self: Sized,
{ ... }
fn interleave_shortest<J>(
self,
other: J
) -> InterleaveShortest<Self, J::IntoIter>ⓘNotable traits for InterleaveShortest<I, J>impl<I, J> Iterator for InterleaveShortest<I, J> where
I: Iterator,
J: Iterator<Item = I::Item>, type Item = I::Item;
where
J: IntoIterator<Item = Self::Item>,
Self: Sized,
{ ... }
fn intersperse(self, element: Self::Item) -> Intersperse<Self>
where
Self: Sized,
Self::Item: Clone,
{ ... }
fn intersperse_with<F>(self, element: F) -> IntersperseWith<Self, F>ⓘNotable traits for IntersperseWith<I, ElemF>impl<I, ElemF> Iterator for IntersperseWith<I, ElemF> where
I: Iterator,
ElemF: IntersperseElement<I::Item>, type Item = I::Item;
where
Self: Sized,
F: FnMut() -> Self::Item,
{ ... }
fn zip_longest<J>(self, other: J) -> ZipLongest<Self, J::IntoIter>ⓘNotable traits for ZipLongest<T, U>impl<T, U> Iterator for ZipLongest<T, U> where
T: Iterator,
U: Iterator, type Item = EitherOrBoth<T::Item, U::Item>;
where
J: IntoIterator,
Self: Sized,
{ ... }
fn zip_eq<J>(self, other: J) -> ZipEq<Self, J::IntoIter>ⓘNotable traits for ZipEq<I, J>impl<I, J> Iterator for ZipEq<I, J> where
I: Iterator,
J: Iterator, type Item = (I::Item, J::Item);
where
J: IntoIterator,
Self: Sized,
{ ... }
fn batching<B, F>(self, f: F) -> Batching<Self, F>ⓘNotable traits for Batching<I, F>impl<B, F, I> Iterator for Batching<I, F> where
I: Iterator,
F: FnMut(&mut I) -> Option<B>, type Item = B;
where
F: FnMut(&mut Self) -> Option<B>,
Self: Sized,
{ ... }
fn group_by<K, F>(self, key: F) -> GroupBy<K, Self, F>
where
Self: Sized,
F: FnMut(&Self::Item) -> K,
K: PartialEq,
{ ... }
fn chunks(self, size: usize) -> IntoChunks<Self>
where
Self: Sized,
{ ... }
fn tuple_windows<T>(self) -> TupleWindows<Self, T>ⓘNotable traits for TupleWindows<I, T>impl<I, T> Iterator for TupleWindows<I, T> where
I: Iterator<Item = T::Item>,
T: HomogeneousTuple + Clone,
T::Item: Clone, type Item = T;
where
Self: Sized + Iterator<Item = T::Item>,
T: HomogeneousTuple,
T::Item: Clone,
{ ... }
fn circular_tuple_windows<T>(self) -> CircularTupleWindows<Self, T>ⓘNotable traits for CircularTupleWindows<I, T>impl<I, T> Iterator for CircularTupleWindows<I, T> where
I: Iterator<Item = T::Item> + Clone,
T: TupleCollect + Clone,
T::Item: Clone, type Item = T;
where
Self: Sized + Clone + Iterator<Item = T::Item> + ExactSizeIterator,
T: TupleCollect + Clone,
T::Item: Clone,
{ ... }
fn tuples<T>(self) -> Tuples<Self, T>ⓘNotable traits for Tuples<I, T>impl<I, T> Iterator for Tuples<I, T> where
I: Iterator<Item = T::Item>,
T: HomogeneousTuple, type Item = T;
where
Self: Sized + Iterator<Item = T::Item>,
T: HomogeneousTuple,
{ ... }
fn tee(self) -> (Tee<Self>, Tee<Self>)
where
Self: Sized,
Self::Item: Clone,
{ ... }
fn step(self, n: usize) -> Step<Self>ⓘNotable traits for Step<I>impl<I> Iterator for Step<I> where
I: Iterator, type Item = I::Item;
where
Self: Sized,
{ ... }
fn map_into<R>(self) -> MapInto<Self, R>
where
Self: Sized,
Self::Item: Into<R>,
{ ... }
fn map_results<F, T, U, E>(self, f: F) -> MapOk<Self, F>
where
Self: Iterator<Item = Result<T, E>> + Sized,
F: FnMut(T) -> U,
{ ... }
fn map_ok<F, T, U, E>(self, f: F) -> MapOk<Self, F>
where
Self: Iterator<Item = Result<T, E>> + Sized,
F: FnMut(T) -> U,
{ ... }
fn filter_ok<F, T, E>(self, f: F) -> FilterOk<Self, F>ⓘNotable traits for FilterOk<I, F>impl<I, F, T, E> Iterator for FilterOk<I, F> where
I: Iterator<Item = Result<T, E>>,
F: FnMut(&T) -> bool, type Item = Result<T, E>;
where
Self: Iterator<Item = Result<T, E>> + Sized,
F: FnMut(&T) -> bool,
{ ... }
fn filter_map_ok<F, T, U, E>(self, f: F) -> FilterMapOk<Self, F>ⓘNotable traits for FilterMapOk<I, F>impl<I, F, T, U, E> Iterator for FilterMapOk<I, F> where
I: Iterator<Item = Result<T, E>>,
F: FnMut(T) -> Option<U>, type Item = Result<U, E>;
where
Self: Iterator<Item = Result<T, E>> + Sized,
F: FnMut(T) -> Option<U>,
{ ... }
fn flatten_ok<T, E>(self) -> FlattenOk<Self, T, E>ⓘNotable traits for FlattenOk<I, T, E>impl<I, T, E> Iterator for FlattenOk<I, T, E> where
I: Iterator<Item = Result<T, E>>,
T: IntoIterator, type Item = Result<T::Item, E>;
where
Self: Iterator<Item = Result<T, E>> + Sized,
T: IntoIterator,
{ ... }
fn merge<J>(self, other: J) -> Merge<Self, J::IntoIter>
where
Self: Sized,
Self::Item: PartialOrd,
J: IntoIterator<Item = Self::Item>,
{ ... }
fn merge_by<J, F>(
self,
other: J,
is_first: F
) -> MergeBy<Self, J::IntoIter, F>ⓘNotable traits for MergeBy<I, J, F>impl<I, J, F> Iterator for MergeBy<I, J, F> where
I: Iterator,
J: Iterator<Item = I::Item>,
F: MergePredicate<I::Item>, type Item = I::Item;
where
Self: Sized,
J: IntoIterator<Item = Self::Item>,
F: FnMut(&Self::Item, &Self::Item) -> bool,
{ ... }
fn merge_join_by<J, F>(
self,
other: J,
cmp_fn: F
) -> MergeJoinBy<Self, J::IntoIter, F>ⓘNotable traits for MergeJoinBy<I, J, F>impl<I, J, F> Iterator for MergeJoinBy<I, J, F> where
I: Iterator,
J: Iterator,
F: FnMut(&I::Item, &J::Item) -> Ordering, type Item = EitherOrBoth<I::Item, J::Item>;
where
J: IntoIterator,
F: FnMut(&Self::Item, &J::Item) -> Ordering,
Self: Sized,
{ ... }
fn kmerge(self) -> KMerge<<Self::Item as IntoIterator>::IntoIter>
where
Self: Sized,
Self::Item: IntoIterator,
<Self::Item as IntoIterator>::Item: PartialOrd,
{ ... }
fn kmerge_by<F>(
self,
first: F
) -> KMergeBy<<Self::Item as IntoIterator>::IntoIter, F>ⓘNotable traits for KMergeBy<I, F>impl<I, F> Iterator for KMergeBy<I, F> where
I: Iterator,
F: KMergePredicate<I::Item>, type Item = I::Item;
where
Self: Sized,
Self::Item: IntoIterator,
F: FnMut(&<Self::Item as IntoIterator>::Item, &<Self::Item as IntoIterator>::Item) -> bool,
{ ... }
fn cartesian_product<J>(self, other: J) -> Product<Self, J::IntoIter>ⓘNotable traits for Product<I, J>impl<I, J> Iterator for Product<I, J> where
I: Iterator,
J: Clone + Iterator,
I::Item: Clone, type Item = (I::Item, J::Item);
where
Self: Sized,
Self::Item: Clone,
J: IntoIterator,
J::IntoIter: Clone,
{ ... }
fn multi_cartesian_product(
self
) -> MultiProduct<<Self::Item as IntoIterator>::IntoIter>ⓘNotable traits for MultiProduct<I>impl<I> Iterator for MultiProduct<I> where
I: Iterator + Clone,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Iterator + Sized,
Self::Item: IntoIterator,
<Self::Item as IntoIterator>::IntoIter: Clone,
<Self::Item as IntoIterator>::Item: Clone,
{ ... }
fn coalesce<F>(self, f: F) -> Coalesce<Self, F>
where
Self: Sized,
F: FnMut(Self::Item, Self::Item) -> Result<Self::Item, (Self::Item, Self::Item)>,
{ ... }
fn dedup(self) -> Dedup<Self>
where
Self: Sized,
Self::Item: PartialEq,
{ ... }
fn dedup_by<Cmp>(self, cmp: Cmp) -> DedupBy<Self, Cmp>
where
Self: Sized,
Cmp: FnMut(&Self::Item, &Self::Item) -> bool,
{ ... }
fn dedup_with_count(self) -> DedupWithCount<Self>
where
Self: Sized,
{ ... }
fn dedup_by_with_count<Cmp>(self, cmp: Cmp) -> DedupByWithCount<Self, Cmp>
where
Self: Sized,
Cmp: FnMut(&Self::Item, &Self::Item) -> bool,
{ ... }
fn duplicates(self) -> Duplicates<Self>
where
Self: Sized,
Self::Item: Eq + Hash,
{ ... }
fn duplicates_by<V, F>(self, f: F) -> DuplicatesBy<Self, V, F>
where
Self: Sized,
V: Eq + Hash,
F: FnMut(&Self::Item) -> V,
{ ... }
fn unique(self) -> Unique<Self>ⓘNotable traits for Unique<I>impl<I> Iterator for Unique<I> where
I: Iterator,
I::Item: Eq + Hash + Clone, type Item = I::Item;
where
Self: Sized,
Self::Item: Clone + Eq + Hash,
{ ... }
fn unique_by<V, F>(self, f: F) -> UniqueBy<Self, V, F>ⓘNotable traits for UniqueBy<I, V, F>impl<I, V, F> Iterator for UniqueBy<I, V, F> where
I: Iterator,
V: Eq + Hash,
F: FnMut(&I::Item) -> V, type Item = I::Item;
where
Self: Sized,
V: Eq + Hash,
F: FnMut(&Self::Item) -> V,
{ ... }
fn peeking_take_while<F>(
&mut self,
accept: F
) -> PeekingTakeWhile<'_, Self, F>ⓘNotable traits for PeekingTakeWhile<'a, I, F>impl<'a, I, F> Iterator for PeekingTakeWhile<'a, I, F> where
I: PeekingNext,
F: FnMut(&I::Item) -> bool, type Item = I::Item;
where
Self: Sized + PeekingNext,
F: FnMut(&Self::Item) -> bool,
{ ... }
fn take_while_ref<F>(&mut self, accept: F) -> TakeWhileRef<'_, Self, F>ⓘNotable traits for TakeWhileRef<'a, I, F>impl<'a, I, F> Iterator for TakeWhileRef<'a, I, F> where
I: Iterator + Clone,
F: FnMut(&I::Item) -> bool, type Item = I::Item;
where
Self: Clone,
F: FnMut(&Self::Item) -> bool,
{ ... }
fn while_some<A>(self) -> WhileSome<Self>ⓘNotable traits for WhileSome<I>impl<I, A> Iterator for WhileSome<I> where
I: Iterator<Item = Option<A>>, type Item = A;
where
Self: Sized + Iterator<Item = Option<A>>,
{ ... }
fn tuple_combinations<T>(self) -> TupleCombinations<Self, T>ⓘNotable traits for TupleCombinations<I, T>impl<I, T> Iterator for TupleCombinations<I, T> where
I: Iterator,
T: HasCombination<I>, type Item = T;
where
Self: Sized + Clone,
Self::Item: Clone,
T: HasCombination<Self>,
{ ... }
fn combinations(self, k: usize) -> Combinations<Self>ⓘNotable traits for Combinations<I>impl<I> Iterator for Combinations<I> where
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Sized,
Self::Item: Clone,
{ ... }
fn combinations_with_replacement(
self,
k: usize
) -> CombinationsWithReplacement<Self>ⓘNotable traits for CombinationsWithReplacement<I>impl<I> Iterator for CombinationsWithReplacement<I> where
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Sized,
Self::Item: Clone,
{ ... }
fn permutations(self, k: usize) -> Permutations<Self>ⓘNotable traits for Permutations<I>impl<I> Iterator for Permutations<I> where
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Sized,
Self::Item: Clone,
{ ... }
fn powerset(self) -> Powerset<Self>ⓘNotable traits for Powerset<I>impl<I> Iterator for Powerset<I> where
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Sized,
Self::Item: Clone,
{ ... }
fn pad_using<F>(self, min: usize, f: F) -> PadUsing<Self, F>ⓘNotable traits for PadUsing<I, F>impl<I, F> Iterator for PadUsing<I, F> where
I: Iterator,
F: FnMut(usize) -> I::Item, type Item = I::Item;
where
Self: Sized,
F: FnMut(usize) -> Self::Item,
{ ... }
fn with_position(self) -> WithPosition<Self>ⓘNotable traits for WithPosition<I>impl<I: Iterator> Iterator for WithPosition<I> type Item = Position<I::Item>;
where
Self: Sized,
{ ... }
fn positions<P>(self, predicate: P) -> Positions<Self, P>ⓘNotable traits for Positions<I, F>impl<I, F> Iterator for Positions<I, F> where
I: Iterator,
F: FnMut(I::Item) -> bool, type Item = usize;
where
Self: Sized,
P: FnMut(Self::Item) -> bool,
{ ... }
fn update<F>(self, updater: F) -> Update<Self, F>ⓘNotable traits for Update<I, F>impl<I, F> Iterator for Update<I, F> where
I: Iterator,
F: FnMut(&mut I::Item), type Item = I::Item;
where
Self: Sized,
F: FnMut(&mut Self::Item),
{ ... }
fn next_tuple<T>(&mut self) -> Option<T>
where
Self: Sized + Iterator<Item = T::Item>,
T: HomogeneousTuple,
{ ... }
fn collect_tuple<T>(self) -> Option<T>
where
Self: Sized + Iterator<Item = T::Item>,
T: HomogeneousTuple,
{ ... }
fn find_position<P>(&mut self, pred: P) -> Option<(usize, Self::Item)>
where
P: FnMut(&Self::Item) -> bool,
{ ... }
fn find_or_last<P>(self, predicate: P) -> Option<Self::Item>
where
Self: Sized,
P: FnMut(&Self::Item) -> bool,
{ ... }
fn find_or_first<P>(self, predicate: P) -> Option<Self::Item>
where
Self: Sized,
P: FnMut(&Self::Item) -> bool,
{ ... }
fn contains<Q>(&mut self, query: &Q) -> bool
where
Self: Sized,
Self::Item: Borrow<Q>,
Q: PartialEq,
{ ... }
fn all_equal(&mut self) -> bool
where
Self: Sized,
Self::Item: PartialEq,
{ ... }
fn all_unique(&mut self) -> bool
where
Self: Sized,
Self::Item: Eq + Hash,
{ ... }
fn dropping(self, n: usize) -> Self
where
Self: Sized,
{ ... }
fn dropping_back(self, n: usize) -> Self
where
Self: Sized,
Self: DoubleEndedIterator,
{ ... }
fn foreach<F>(self, f: F)
where
F: FnMut(Self::Item),
Self: Sized,
{ ... }
fn concat(self) -> Self::Item
where
Self: Sized,
Self::Item: Extend<<<Self as Iterator>::Item as IntoIterator>::Item> + IntoIterator + Default,
{ ... }
fn collect_vec(self) -> Vec<Self::Item>
where
Self: Sized,
{ ... }
fn try_collect<T, U, E>(self) -> Result<U, E>
where
Self: Sized + Iterator<Item = Result<T, E>>,
Result<U, E>: FromIterator<Result<T, E>>,
{ ... }
fn set_from<'a, A: 'a, J>(&mut self, from: J) -> usize
where
Self: Iterator<Item = &'a mut A>,
J: IntoIterator<Item = A>,
{ ... }
fn join(&mut self, sep: &str) -> String
where
Self::Item: Display,
{ ... }
fn format(self, sep: &str) -> Format<'_, Self>
where
Self: Sized,
{ ... }
fn format_with<F>(self, sep: &str, format: F) -> FormatWith<'_, Self, F>
where
Self: Sized,
F: FnMut(Self::Item, &mut dyn FnMut(&dyn Display) -> Result) -> Result,
{ ... }
fn fold_results<A, E, B, F>(&mut self, start: B, f: F) -> Result<B, E>
where
Self: Iterator<Item = Result<A, E>>,
F: FnMut(B, A) -> B,
{ ... }
fn fold_ok<A, E, B, F>(&mut self, start: B, f: F) -> Result<B, E>
where
Self: Iterator<Item = Result<A, E>>,
F: FnMut(B, A) -> B,
{ ... }
fn fold_options<A, B, F>(&mut self, start: B, f: F) -> Option<B>
where
Self: Iterator<Item = Option<A>>,
F: FnMut(B, A) -> B,
{ ... }
fn fold1<F>(self, f: F) -> Option<Self::Item>
where
F: FnMut(Self::Item, Self::Item) -> Self::Item,
Self: Sized,
{ ... }
fn tree_fold1<F>(self, f: F) -> Option<Self::Item>
where
F: FnMut(Self::Item, Self::Item) -> Self::Item,
Self: Sized,
{ ... }
fn fold_while<B, F>(&mut self, init: B, f: F) -> FoldWhile<B>
where
Self: Sized,
F: FnMut(B, Self::Item) -> FoldWhile<B>,
{ ... }
fn sum1<S>(self) -> Option<S>
where
Self: Sized,
S: Sum<Self::Item>,
{ ... }
fn product1<P>(self) -> Option<P>
where
Self: Sized,
P: Product<Self::Item>,
{ ... }
fn sorted_unstable(self) -> IntoIter<Self::Item>
where
Self: Sized,
Self::Item: Ord,
{ ... }
fn sorted_unstable_by<F>(self, cmp: F) -> IntoIter<Self::Item>
where
Self: Sized,
F: FnMut(&Self::Item, &Self::Item) -> Ordering,
{ ... }
fn sorted_unstable_by_key<K, F>(self, f: F) -> IntoIter<Self::Item>
where
Self: Sized,
K: Ord,
F: FnMut(&Self::Item) -> K,
{ ... }
fn sorted(self) -> IntoIter<Self::Item>
where
Self: Sized,
Self::Item: Ord,
{ ... }
fn sorted_by<F>(self, cmp: F) -> IntoIter<Self::Item>
where
Self: Sized,
F: FnMut(&Self::Item, &Self::Item) -> Ordering,
{ ... }
fn sorted_by_key<K, F>(self, f: F) -> IntoIter<Self::Item>
where
Self: Sized,
K: Ord,
F: FnMut(&Self::Item) -> K,
{ ... }
fn sorted_by_cached_key<K, F>(self, f: F) -> IntoIter<Self::Item>
where
Self: Sized,
K: Ord,
F: FnMut(&Self::Item) -> K,
{ ... }
fn k_smallest(self, k: usize) -> IntoIter<Self::Item>
where
Self: Sized,
Self::Item: Ord,
{ ... }
fn partition_map<A, B, F, L, R>(self, predicate: F) -> (A, B)
where
Self: Sized,
F: FnMut(Self::Item) -> Either<L, R>,
A: Default + Extend<L>,
B: Default + Extend<R>,
{ ... }
fn partition_result<A, B, T, E>(self) -> (A, B)
where
Self: Iterator<Item = Result<T, E>> + Sized,
A: Default + Extend<T>,
B: Default + Extend<E>,
{ ... }
fn into_group_map<K, V>(self) -> HashMap<K, Vec<V>>
where
Self: Iterator<Item = (K, V)> + Sized,
K: Hash + Eq,
{ ... }
fn into_group_map_by<K, V, F>(self, f: F) -> HashMap<K, Vec<V>>
where
Self: Iterator<Item = V> + Sized,
K: Hash + Eq,
F: Fn(&V) -> K,
{ ... }
fn into_grouping_map<K, V>(self) -> GroupingMap<Self>
where
Self: Iterator<Item = (K, V)> + Sized,
K: Hash + Eq,
{ ... }
fn into_grouping_map_by<K, V, F>(
self,
key_mapper: F
) -> GroupingMapBy<Self, F>
where
Self: Iterator<Item = V> + Sized,
K: Hash + Eq,
F: FnMut(&V) -> K,
{ ... }
fn minmax(self) -> MinMaxResult<Self::Item>
where
Self: Sized,
Self::Item: PartialOrd,
{ ... }
fn minmax_by_key<K, F>(self, key: F) -> MinMaxResult<Self::Item>
where
Self: Sized,
K: PartialOrd,
F: FnMut(&Self::Item) -> K,
{ ... }
fn minmax_by<F>(self, compare: F) -> MinMaxResult<Self::Item>
where
Self: Sized,
F: FnMut(&Self::Item, &Self::Item) -> Ordering,
{ ... }
fn position_max(self) -> Option<usize>
where
Self: Sized,
Self::Item: Ord,
{ ... }
fn position_max_by_key<K, F>(self, key: F) -> Option<usize>
where
Self: Sized,
K: Ord,
F: FnMut(&Self::Item) -> K,
{ ... }
fn position_max_by<F>(self, compare: F) -> Option<usize>
where
Self: Sized,
F: FnMut(&Self::Item, &Self::Item) -> Ordering,
{ ... }
fn position_min(self) -> Option<usize>
where
Self: Sized,
Self::Item: Ord,
{ ... }
fn position_min_by_key<K, F>(self, key: F) -> Option<usize>
where
Self: Sized,
K: Ord,
F: FnMut(&Self::Item) -> K,
{ ... }
fn position_min_by<F>(self, compare: F) -> Option<usize>
where
Self: Sized,
F: FnMut(&Self::Item, &Self::Item) -> Ordering,
{ ... }
fn position_minmax(self) -> MinMaxResult<usize>
where
Self: Sized,
Self::Item: PartialOrd,
{ ... }
fn position_minmax_by_key<K, F>(self, key: F) -> MinMaxResult<usize>
where
Self: Sized,
K: PartialOrd,
F: FnMut(&Self::Item) -> K,
{ ... }
fn position_minmax_by<F>(self, compare: F) -> MinMaxResult<usize>
where
Self: Sized,
F: FnMut(&Self::Item, &Self::Item) -> Ordering,
{ ... }
fn exactly_one(self) -> Result<Self::Item, ExactlyOneError<Self>>
where
Self: Sized,
{ ... }
fn at_most_one(self) -> Result<Option<Self::Item>, ExactlyOneError<Self>>
where
Self: Sized,
{ ... }
fn multipeek(self) -> MultiPeek<Self>ⓘNotable traits for MultiPeek<I>impl<I> Iterator for MultiPeek<I> where
I: Iterator, type Item = I::Item;
where
Self: Sized,
{ ... }
fn counts(self) -> HashMap<Self::Item, usize>
where
Self: Sized,
Self::Item: Eq + Hash,
{ ... }
fn counts_by<K, F>(self, f: F) -> HashMap<K, usize>
where
Self: Sized,
K: Eq + Hash,
F: FnMut(Self::Item) -> K,
{ ... }
fn multiunzip<FromI>(self) -> FromI
where
Self: Sized + MultiUnzip<FromI>,
{ ... }
}
Expand description
An Iterator
blanket implementation that provides extra adaptors and
methods.
This trait defines a number of methods. They are divided into two groups:
-
Adaptors take an iterator and parameter as input, and return a new iterator value. These are listed first in the trait. An example of an adaptor is
.interleave()
-
Regular methods are those that don’t return iterators and instead return a regular value of some other kind.
.next_tuple()
is an example and the first regular method in the list.
Provided methods
fn interleave<J>(self, other: J) -> Interleave<Self, J::IntoIter>ⓘNotable traits for Interleave<I, J>impl<I, J> Iterator for Interleave<I, J> where
I: Iterator,
J: Iterator<Item = I::Item>, type Item = I::Item;
where
J: IntoIterator<Item = Self::Item>,
Self: Sized,
fn interleave<J>(self, other: J) -> Interleave<Self, J::IntoIter>ⓘNotable traits for Interleave<I, J>impl<I, J> Iterator for Interleave<I, J> where
I: Iterator,
J: Iterator<Item = I::Item>, type Item = I::Item;
where
J: IntoIterator<Item = Self::Item>,
Self: Sized,
I: Iterator,
J: Iterator<Item = I::Item>, type Item = I::Item;
Alternate elements from two iterators until both have run out.
Iterator element type is Self::Item
.
This iterator is fused.
use itertools::Itertools;
let it = (1..7).interleave(vec![-1, -2]);
itertools::assert_equal(it, vec![1, -1, 2, -2, 3, 4, 5, 6]);
fn interleave_shortest<J>(
self,
other: J
) -> InterleaveShortest<Self, J::IntoIter>ⓘNotable traits for InterleaveShortest<I, J>impl<I, J> Iterator for InterleaveShortest<I, J> where
I: Iterator,
J: Iterator<Item = I::Item>, type Item = I::Item;
where
J: IntoIterator<Item = Self::Item>,
Self: Sized,
fn interleave_shortest<J>(
self,
other: J
) -> InterleaveShortest<Self, J::IntoIter>ⓘNotable traits for InterleaveShortest<I, J>impl<I, J> Iterator for InterleaveShortest<I, J> where
I: Iterator,
J: Iterator<Item = I::Item>, type Item = I::Item;
where
J: IntoIterator<Item = Self::Item>,
Self: Sized,
I: Iterator,
J: Iterator<Item = I::Item>, type Item = I::Item;
Alternate elements from two iterators until at least one of them has run out.
Iterator element type is Self::Item
.
use itertools::Itertools;
let it = (1..7).interleave_shortest(vec![-1, -2]);
itertools::assert_equal(it, vec![1, -1, 2, -2, 3]);
fn intersperse(self, element: Self::Item) -> Intersperse<Self> where
Self: Sized,
Self::Item: Clone,
fn intersperse(self, element: Self::Item) -> Intersperse<Self> where
Self: Sized,
Self::Item: Clone,
An iterator adaptor to insert a particular value between each element of the adapted iterator.
Iterator element type is Self::Item
.
This iterator is fused.
use itertools::Itertools;
itertools::assert_equal((0..3).intersperse(8), vec![0, 8, 1, 8, 2]);
fn intersperse_with<F>(self, element: F) -> IntersperseWith<Self, F>ⓘNotable traits for IntersperseWith<I, ElemF>impl<I, ElemF> Iterator for IntersperseWith<I, ElemF> where
I: Iterator,
ElemF: IntersperseElement<I::Item>, type Item = I::Item;
where
Self: Sized,
F: FnMut() -> Self::Item,
fn intersperse_with<F>(self, element: F) -> IntersperseWith<Self, F>ⓘNotable traits for IntersperseWith<I, ElemF>impl<I, ElemF> Iterator for IntersperseWith<I, ElemF> where
I: Iterator,
ElemF: IntersperseElement<I::Item>, type Item = I::Item;
where
Self: Sized,
F: FnMut() -> Self::Item,
I: Iterator,
ElemF: IntersperseElement<I::Item>, type Item = I::Item;
An iterator adaptor to insert a particular value created by a function between each element of the adapted iterator.
Iterator element type is Self::Item
.
This iterator is fused.
use itertools::Itertools;
let mut i = 10;
itertools::assert_equal((0..3).intersperse_with(|| { i -= 1; i }), vec![0, 9, 1, 8, 2]);
assert_eq!(i, 8);
fn zip_longest<J>(self, other: J) -> ZipLongest<Self, J::IntoIter>ⓘNotable traits for ZipLongest<T, U>impl<T, U> Iterator for ZipLongest<T, U> where
T: Iterator,
U: Iterator, type Item = EitherOrBoth<T::Item, U::Item>;
where
J: IntoIterator,
Self: Sized,
fn zip_longest<J>(self, other: J) -> ZipLongest<Self, J::IntoIter>ⓘNotable traits for ZipLongest<T, U>impl<T, U> Iterator for ZipLongest<T, U> where
T: Iterator,
U: Iterator, type Item = EitherOrBoth<T::Item, U::Item>;
where
J: IntoIterator,
Self: Sized,
T: Iterator,
U: Iterator, type Item = EitherOrBoth<T::Item, U::Item>;
Create an iterator which iterates over both this and the specified iterator simultaneously, yielding pairs of two optional elements.
This iterator is fused.
As long as neither input iterator is exhausted yet, it yields two values
via EitherOrBoth::Both
.
When the parameter iterator is exhausted, it only yields a value from the
self
iterator via EitherOrBoth::Left
.
When the self
iterator is exhausted, it only yields a value from the
parameter iterator via EitherOrBoth::Right
.
When both iterators return None
, all further invocations of .next()
will return None
.
Iterator element type is
EitherOrBoth<Self::Item, J::Item>
.
use itertools::EitherOrBoth::{Both, Right};
use itertools::Itertools;
let it = (0..1).zip_longest(1..3);
itertools::assert_equal(it, vec![Both(0, 1), Right(2)]);
Create an iterator which iterates over both this and the specified iterator simultaneously, yielding pairs of elements.
Panics if the iterators reach an end and they are not of equal lengths.
A “meta iterator adaptor”. Its closure receives a reference to the iterator and may pick off as many elements as it likes, to produce the next iterator element.
Iterator element type is B
.
use itertools::Itertools;
// An adaptor that gathers elements in pairs
let pit = (0..4).batching(|it| {
match it.next() {
None => None,
Some(x) => match it.next() {
None => None,
Some(y) => Some((x, y)),
}
}
});
itertools::assert_equal(pit, vec![(0, 1), (2, 3)]);
Return an iterable that can group iterator elements. Consecutive elements that map to the same key (“runs”), are assigned to the same group.
GroupBy
is the storage for the lazy grouping operation.
If the groups are consumed in order, or if each group’s iterator is
dropped without keeping it around, then GroupBy
uses no
allocations. It needs allocations only if several group iterators
are alive at the same time.
This type implements IntoIterator
(it is not an iterator
itself), because the group iterators need to borrow from this
value. It should be stored in a local variable or temporary and
iterated.
Iterator element type is (K, Group)
: the group’s key and the
group iterator.
use itertools::Itertools;
// group data into runs of larger than zero or not.
let data = vec![1, 3, -2, -2, 1, 0, 1, 2];
// groups: |---->|------>|--------->|
// Note: The `&` is significant here, `GroupBy` is iterable
// only by reference. You can also call `.into_iter()` explicitly.
let mut data_grouped = Vec::new();
for (key, group) in &data.into_iter().group_by(|elt| *elt >= 0) {
data_grouped.push((key, group.collect()));
}
assert_eq!(data_grouped, vec![(true, vec![1, 3]), (false, vec![-2, -2]), (true, vec![1, 0, 1, 2])]);
fn chunks(self, size: usize) -> IntoChunks<Self> where
Self: Sized,
fn chunks(self, size: usize) -> IntoChunks<Self> where
Self: Sized,
Return an iterable that can chunk the iterator.
Yield subiterators (chunks) that each yield a fixed number elements,
determined by size
. The last chunk will be shorter if there aren’t
enough elements.
IntoChunks
is based on GroupBy
: it is iterable (implements
IntoIterator
, not Iterator
), and it only buffers if several
chunk iterators are alive at the same time.
Iterator element type is Chunk
, each chunk’s iterator.
Panics if size
is 0.
use itertools::Itertools;
let data = vec![1, 1, 2, -2, 6, 0, 3, 1];
//chunk size=3 |------->|-------->|--->|
// Note: The `&` is significant here, `IntoChunks` is iterable
// only by reference. You can also call `.into_iter()` explicitly.
for chunk in &data.into_iter().chunks(3) {
// Check that the sum of each chunk is 4.
assert_eq!(4, chunk.sum());
}
fn tuple_windows<T>(self) -> TupleWindows<Self, T>ⓘNotable traits for TupleWindows<I, T>impl<I, T> Iterator for TupleWindows<I, T> where
I: Iterator<Item = T::Item>,
T: HomogeneousTuple + Clone,
T::Item: Clone, type Item = T;
where
Self: Sized + Iterator<Item = T::Item>,
T: HomogeneousTuple,
T::Item: Clone,
fn tuple_windows<T>(self) -> TupleWindows<Self, T>ⓘNotable traits for TupleWindows<I, T>impl<I, T> Iterator for TupleWindows<I, T> where
I: Iterator<Item = T::Item>,
T: HomogeneousTuple + Clone,
T::Item: Clone, type Item = T;
where
Self: Sized + Iterator<Item = T::Item>,
T: HomogeneousTuple,
T::Item: Clone,
I: Iterator<Item = T::Item>,
T: HomogeneousTuple + Clone,
T::Item: Clone, type Item = T;
Return an iterator over all contiguous windows producing tuples of a specific size (up to 12).
tuple_windows
clones the iterator elements so that they can be
part of successive windows, this makes it most suited for iterators
of references and other values that are cheap to copy.
use itertools::Itertools;
let mut v = Vec::new();
// pairwise iteration
for (a, b) in (1..5).tuple_windows() {
v.push((a, b));
}
assert_eq!(v, vec![(1, 2), (2, 3), (3, 4)]);
let mut it = (1..5).tuple_windows();
assert_eq!(Some((1, 2, 3)), it.next());
assert_eq!(Some((2, 3, 4)), it.next());
assert_eq!(None, it.next());
// this requires a type hint
let it = (1..5).tuple_windows::<(_, _, _)>();
itertools::assert_equal(it, vec![(1, 2, 3), (2, 3, 4)]);
// you can also specify the complete type
use itertools::TupleWindows;
use std::ops::Range;
let it: TupleWindows<Range<u32>, (u32, u32, u32)> = (1..5).tuple_windows();
itertools::assert_equal(it, vec![(1, 2, 3), (2, 3, 4)]);
fn circular_tuple_windows<T>(self) -> CircularTupleWindows<Self, T>ⓘNotable traits for CircularTupleWindows<I, T>impl<I, T> Iterator for CircularTupleWindows<I, T> where
I: Iterator<Item = T::Item> + Clone,
T: TupleCollect + Clone,
T::Item: Clone, type Item = T;
where
Self: Sized + Clone + Iterator<Item = T::Item> + ExactSizeIterator,
T: TupleCollect + Clone,
T::Item: Clone,
fn circular_tuple_windows<T>(self) -> CircularTupleWindows<Self, T>ⓘNotable traits for CircularTupleWindows<I, T>impl<I, T> Iterator for CircularTupleWindows<I, T> where
I: Iterator<Item = T::Item> + Clone,
T: TupleCollect + Clone,
T::Item: Clone, type Item = T;
where
Self: Sized + Clone + Iterator<Item = T::Item> + ExactSizeIterator,
T: TupleCollect + Clone,
T::Item: Clone,
I: Iterator<Item = T::Item> + Clone,
T: TupleCollect + Clone,
T::Item: Clone, type Item = T;
Return an iterator over all windows, wrapping back to the first elements when the window would otherwise exceed the length of the iterator, producing tuples of a specific size (up to 12).
circular_tuple_windows
clones the iterator elements so that they can be
part of successive windows, this makes it most suited for iterators
of references and other values that are cheap to copy.
use itertools::Itertools;
let mut v = Vec::new();
for (a, b) in (1..5).circular_tuple_windows() {
v.push((a, b));
}
assert_eq!(v, vec![(1, 2), (2, 3), (3, 4), (4, 1)]);
let mut it = (1..5).circular_tuple_windows();
assert_eq!(Some((1, 2, 3)), it.next());
assert_eq!(Some((2, 3, 4)), it.next());
assert_eq!(Some((3, 4, 1)), it.next());
assert_eq!(Some((4, 1, 2)), it.next());
assert_eq!(None, it.next());
// this requires a type hint
let it = (1..5).circular_tuple_windows::<(_, _, _)>();
itertools::assert_equal(it, vec![(1, 2, 3), (2, 3, 4), (3, 4, 1), (4, 1, 2)]);
Return an iterator that groups the items in tuples of a specific size (up to 12).
See also the method .next_tuple()
.
use itertools::Itertools;
let mut v = Vec::new();
for (a, b) in (1..5).tuples() {
v.push((a, b));
}
assert_eq!(v, vec![(1, 2), (3, 4)]);
let mut it = (1..7).tuples();
assert_eq!(Some((1, 2, 3)), it.next());
assert_eq!(Some((4, 5, 6)), it.next());
assert_eq!(None, it.next());
// this requires a type hint
let it = (1..7).tuples::<(_, _, _)>();
itertools::assert_equal(it, vec![(1, 2, 3), (4, 5, 6)]);
// you can also specify the complete type
use itertools::Tuples;
use std::ops::Range;
let it: Tuples<Range<u32>, (u32, u32, u32)> = (1..7).tuples();
itertools::assert_equal(it, vec![(1, 2, 3), (4, 5, 6)]);
See also Tuples::into_buffer
.
Split into an iterator pair that both yield all elements from the original iterator.
Note: If the iterator is clonable, prefer using that instead of using this method. It is likely to be more efficient.
Iterator element type is Self::Item
.
use itertools::Itertools;
let xs = vec![0, 1, 2, 3];
let (mut t1, t2) = xs.into_iter().tee();
itertools::assert_equal(t1.next(), Some(0));
itertools::assert_equal(t2, 0..4);
itertools::assert_equal(t1, 1..4);
Use std .step_by() instead
Return an iterator adaptor that steps n
elements in the base iterator
for each iteration.
The iterator steps by yielding the next element from the base iterator,
then skipping forward n - 1
elements.
Iterator element type is Self::Item
.
Panics if the step is 0.
use itertools::Itertools;
let it = (0..8).step(3);
itertools::assert_equal(it, vec![0, 3, 6]);
Convert each item of the iterator using the Into
trait.
use itertools::Itertools;
(1i32..42i32).map_into::<f64>().collect_vec();
Return an iterator adaptor that applies the provided closure
to every Result::Ok
value. Result::Err
values are
unchanged.
use itertools::Itertools;
let input = vec![Ok(41), Err(false), Ok(11)];
let it = input.into_iter().map_ok(|i| i + 1);
itertools::assert_equal(it, vec![Ok(42), Err(false), Ok(12)]);
Return an iterator adaptor that filters every Result::Ok
value with the provided closure. Result::Err
values are
unchanged.
use itertools::Itertools;
let input = vec![Ok(22), Err(false), Ok(11)];
let it = input.into_iter().filter_ok(|&i| i > 20);
itertools::assert_equal(it, vec![Ok(22), Err(false)]);
fn filter_map_ok<F, T, U, E>(self, f: F) -> FilterMapOk<Self, F>ⓘNotable traits for FilterMapOk<I, F>impl<I, F, T, U, E> Iterator for FilterMapOk<I, F> where
I: Iterator<Item = Result<T, E>>,
F: FnMut(T) -> Option<U>, type Item = Result<U, E>;
where
Self: Iterator<Item = Result<T, E>> + Sized,
F: FnMut(T) -> Option<U>,
fn filter_map_ok<F, T, U, E>(self, f: F) -> FilterMapOk<Self, F>ⓘNotable traits for FilterMapOk<I, F>impl<I, F, T, U, E> Iterator for FilterMapOk<I, F> where
I: Iterator<Item = Result<T, E>>,
F: FnMut(T) -> Option<U>, type Item = Result<U, E>;
where
Self: Iterator<Item = Result<T, E>> + Sized,
F: FnMut(T) -> Option<U>,
I: Iterator<Item = Result<T, E>>,
F: FnMut(T) -> Option<U>, type Item = Result<U, E>;
Return an iterator adaptor that filters and transforms every
Result::Ok
value with the provided closure. Result::Err
values are unchanged.
use itertools::Itertools;
let input = vec![Ok(22), Err(false), Ok(11)];
let it = input.into_iter().filter_map_ok(|i| if i > 20 { Some(i * 2) } else { None });
itertools::assert_equal(it, vec![Ok(44), Err(false)]);
Return an iterator adaptor that flattens every Result::Ok
value into
a series of Result::Ok
values. Result::Err
values are unchanged.
This is useful when you have some common error type for your crate and
need to propogate it upwards, but the Result::Ok
case needs to be flattened.
use itertools::Itertools;
let input = vec![Ok(0..2), Err(false), Ok(2..4)];
let it = input.iter().cloned().flatten_ok();
itertools::assert_equal(it.clone(), vec![Ok(0), Ok(1), Err(false), Ok(2), Ok(3)]);
// This can also be used to propogate errors when collecting.
let output_result: Result<Vec<i32>, bool> = it.collect();
assert_eq!(output_result, Err(false));
fn merge<J>(self, other: J) -> Merge<Self, J::IntoIter> where
Self: Sized,
Self::Item: PartialOrd,
J: IntoIterator<Item = Self::Item>,
fn merge<J>(self, other: J) -> Merge<Self, J::IntoIter> where
Self: Sized,
Self::Item: PartialOrd,
J: IntoIterator<Item = Self::Item>,
Return an iterator adaptor that merges the two base iterators in ascending order. If both base iterators are sorted (ascending), the result is sorted.
Iterator element type is Self::Item
.
use itertools::Itertools;
let a = (0..11).step(3);
let b = (0..11).step(5);
let it = a.merge(b);
itertools::assert_equal(it, vec![0, 0, 3, 5, 6, 9, 10]);
fn merge_by<J, F>(self, other: J, is_first: F) -> MergeBy<Self, J::IntoIter, F>ⓘNotable traits for MergeBy<I, J, F>impl<I, J, F> Iterator for MergeBy<I, J, F> where
I: Iterator,
J: Iterator<Item = I::Item>,
F: MergePredicate<I::Item>, type Item = I::Item;
where
Self: Sized,
J: IntoIterator<Item = Self::Item>,
F: FnMut(&Self::Item, &Self::Item) -> bool,
fn merge_by<J, F>(self, other: J, is_first: F) -> MergeBy<Self, J::IntoIter, F>ⓘNotable traits for MergeBy<I, J, F>impl<I, J, F> Iterator for MergeBy<I, J, F> where
I: Iterator,
J: Iterator<Item = I::Item>,
F: MergePredicate<I::Item>, type Item = I::Item;
where
Self: Sized,
J: IntoIterator<Item = Self::Item>,
F: FnMut(&Self::Item, &Self::Item) -> bool,
I: Iterator,
J: Iterator<Item = I::Item>,
F: MergePredicate<I::Item>, type Item = I::Item;
Return an iterator adaptor that merges the two base iterators in order.
This is much like .merge()
but allows for a custom ordering.
This can be especially useful for sequences of tuples.
Iterator element type is Self::Item
.
use itertools::Itertools;
let a = (0..).zip("bc".chars());
let b = (0..).zip("ad".chars());
let it = a.merge_by(b, |x, y| x.1 <= y.1);
itertools::assert_equal(it, vec![(0, 'a'), (0, 'b'), (1, 'c'), (1, 'd')]);
fn merge_join_by<J, F>(
self,
other: J,
cmp_fn: F
) -> MergeJoinBy<Self, J::IntoIter, F>ⓘNotable traits for MergeJoinBy<I, J, F>impl<I, J, F> Iterator for MergeJoinBy<I, J, F> where
I: Iterator,
J: Iterator,
F: FnMut(&I::Item, &J::Item) -> Ordering, type Item = EitherOrBoth<I::Item, J::Item>;
where
J: IntoIterator,
F: FnMut(&Self::Item, &J::Item) -> Ordering,
Self: Sized,
fn merge_join_by<J, F>(
self,
other: J,
cmp_fn: F
) -> MergeJoinBy<Self, J::IntoIter, F>ⓘNotable traits for MergeJoinBy<I, J, F>impl<I, J, F> Iterator for MergeJoinBy<I, J, F> where
I: Iterator,
J: Iterator,
F: FnMut(&I::Item, &J::Item) -> Ordering, type Item = EitherOrBoth<I::Item, J::Item>;
where
J: IntoIterator,
F: FnMut(&Self::Item, &J::Item) -> Ordering,
Self: Sized,
I: Iterator,
J: Iterator,
F: FnMut(&I::Item, &J::Item) -> Ordering, type Item = EitherOrBoth<I::Item, J::Item>;
Create an iterator that merges items from both this and the specified iterator in ascending order.
It chooses whether to pair elements based on the Ordering
returned by the
specified compare function. At any point, inspecting the tip of the
iterators I
and J
as items i
of type I::Item
and j
of type
J::Item
respectively, the resulting iterator will:
- Emit
EitherOrBoth::Left(i)
wheni < j
, and removei
from its source iterator - Emit
EitherOrBoth::Right(j)
wheni > j
, and removej
from its source iterator - Emit
EitherOrBoth::Both(i, j)
wheni == j
, and remove bothi
andj
from their respective source iterators
use itertools::Itertools;
use itertools::EitherOrBoth::{Left, Right, Both};
let multiples_of_2 = (0..10).step(2);
let multiples_of_3 = (0..10).step(3);
itertools::assert_equal(
multiples_of_2.merge_join_by(multiples_of_3, |i, j| i.cmp(j)),
vec![Both(0, 0), Left(2), Right(3), Left(4), Both(6, 6), Left(8), Right(9)]
);
fn kmerge(self) -> KMerge<<Self::Item as IntoIterator>::IntoIter> where
Self: Sized,
Self::Item: IntoIterator,
<Self::Item as IntoIterator>::Item: PartialOrd,
fn kmerge(self) -> KMerge<<Self::Item as IntoIterator>::IntoIter> where
Self: Sized,
Self::Item: IntoIterator,
<Self::Item as IntoIterator>::Item: PartialOrd,
Return an iterator adaptor that flattens an iterator of iterators by merging them in ascending order.
If all base iterators are sorted (ascending), the result is sorted.
Iterator element type is Self::Item
.
use itertools::Itertools;
let a = (0..6).step(3);
let b = (1..6).step(3);
let c = (2..6).step(3);
let it = vec![a, b, c].into_iter().kmerge();
itertools::assert_equal(it, vec![0, 1, 2, 3, 4, 5]);
fn kmerge_by<F>(
self,
first: F
) -> KMergeBy<<Self::Item as IntoIterator>::IntoIter, F>ⓘNotable traits for KMergeBy<I, F>impl<I, F> Iterator for KMergeBy<I, F> where
I: Iterator,
F: KMergePredicate<I::Item>, type Item = I::Item;
where
Self: Sized,
Self::Item: IntoIterator,
F: FnMut(&<Self::Item as IntoIterator>::Item, &<Self::Item as IntoIterator>::Item) -> bool,
fn kmerge_by<F>(
self,
first: F
) -> KMergeBy<<Self::Item as IntoIterator>::IntoIter, F>ⓘNotable traits for KMergeBy<I, F>impl<I, F> Iterator for KMergeBy<I, F> where
I: Iterator,
F: KMergePredicate<I::Item>, type Item = I::Item;
where
Self: Sized,
Self::Item: IntoIterator,
F: FnMut(&<Self::Item as IntoIterator>::Item, &<Self::Item as IntoIterator>::Item) -> bool,
I: Iterator,
F: KMergePredicate<I::Item>, type Item = I::Item;
Return an iterator adaptor that flattens an iterator of iterators by merging them according to the given closure.
The closure first
is called with two elements a, b and should
return true
if a is ordered before b.
If all base iterators are sorted according to first
, the result is
sorted.
Iterator element type is Self::Item
.
use itertools::Itertools;
let a = vec![-1f64, 2., 3., -5., 6., -7.];
let b = vec![0., 2., -4.];
let mut it = vec![a, b].into_iter().kmerge_by(|a, b| a.abs() < b.abs());
assert_eq!(it.next(), Some(0.));
assert_eq!(it.last(), Some(-7.));
fn cartesian_product<J>(self, other: J) -> Product<Self, J::IntoIter>ⓘNotable traits for Product<I, J>impl<I, J> Iterator for Product<I, J> where
I: Iterator,
J: Clone + Iterator,
I::Item: Clone, type Item = (I::Item, J::Item);
where
Self: Sized,
Self::Item: Clone,
J: IntoIterator,
J::IntoIter: Clone,
fn cartesian_product<J>(self, other: J) -> Product<Self, J::IntoIter>ⓘNotable traits for Product<I, J>impl<I, J> Iterator for Product<I, J> where
I: Iterator,
J: Clone + Iterator,
I::Item: Clone, type Item = (I::Item, J::Item);
where
Self: Sized,
Self::Item: Clone,
J: IntoIterator,
J::IntoIter: Clone,
I: Iterator,
J: Clone + Iterator,
I::Item: Clone, type Item = (I::Item, J::Item);
Return an iterator adaptor that iterates over the cartesian product of
the element sets of two iterators self
and J
.
Iterator element type is (Self::Item, J::Item)
.
use itertools::Itertools;
let it = (0..2).cartesian_product("αβ".chars());
itertools::assert_equal(it, vec![(0, 'α'), (0, 'β'), (1, 'α'), (1, 'β')]);
fn multi_cartesian_product(
self
) -> MultiProduct<<Self::Item as IntoIterator>::IntoIter>ⓘNotable traits for MultiProduct<I>impl<I> Iterator for MultiProduct<I> where
I: Iterator + Clone,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Iterator + Sized,
Self::Item: IntoIterator,
<Self::Item as IntoIterator>::IntoIter: Clone,
<Self::Item as IntoIterator>::Item: Clone,
fn multi_cartesian_product(
self
) -> MultiProduct<<Self::Item as IntoIterator>::IntoIter>ⓘNotable traits for MultiProduct<I>impl<I> Iterator for MultiProduct<I> where
I: Iterator + Clone,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Iterator + Sized,
Self::Item: IntoIterator,
<Self::Item as IntoIterator>::IntoIter: Clone,
<Self::Item as IntoIterator>::Item: Clone,
I: Iterator + Clone,
I::Item: Clone, type Item = Vec<I::Item>;
Return an iterator adaptor that iterates over the cartesian product of
all subiterators returned by meta-iterator self
.
All provided iterators must yield the same Item
type. To generate
the product of iterators yielding multiple types, use the
iproduct
macro instead.
The iterator element type is Vec<T>
, where T
is the iterator element
of the subiterators.
use itertools::Itertools;
let mut multi_prod = (0..3).map(|i| (i * 2)..(i * 2 + 2))
.multi_cartesian_product();
assert_eq!(multi_prod.next(), Some(vec![0, 2, 4]));
assert_eq!(multi_prod.next(), Some(vec![0, 2, 5]));
assert_eq!(multi_prod.next(), Some(vec![0, 3, 4]));
assert_eq!(multi_prod.next(), Some(vec![0, 3, 5]));
assert_eq!(multi_prod.next(), Some(vec![1, 2, 4]));
assert_eq!(multi_prod.next(), Some(vec![1, 2, 5]));
assert_eq!(multi_prod.next(), Some(vec![1, 3, 4]));
assert_eq!(multi_prod.next(), Some(vec![1, 3, 5]));
assert_eq!(multi_prod.next(), None);
Return an iterator adaptor that uses the passed-in closure to optionally merge together consecutive elements.
The closure f
is passed two elements, previous
and current
and may
return either (1) Ok(combined)
to merge the two values or
(2) Err((previous', current'))
to indicate they can’t be merged.
In (2), the value previous'
is emitted by the iterator.
Either (1) combined
or (2) current'
becomes the previous value
when coalesce continues with the next pair of elements to merge. The
value that remains at the end is also emitted by the iterator.
Iterator element type is Self::Item
.
This iterator is fused.
use itertools::Itertools;
// sum same-sign runs together
let data = vec![-1., -2., -3., 3., 1., 0., -1.];
itertools::assert_equal(data.into_iter().coalesce(|x, y|
if (x >= 0.) == (y >= 0.) {
Ok(x + y)
} else {
Err((x, y))
}),
vec![-6., 4., -1.]);
Remove duplicates from sections of consecutive identical elements. If the iterator is sorted, all elements will be unique.
Iterator element type is Self::Item
.
This iterator is fused.
use itertools::Itertools;
let data = vec![1., 1., 2., 3., 3., 2., 2.];
itertools::assert_equal(data.into_iter().dedup(),
vec![1., 2., 3., 2.]);
Remove duplicates from sections of consecutive identical elements, determining equality using a comparison function. If the iterator is sorted, all elements will be unique.
Iterator element type is Self::Item
.
This iterator is fused.
use itertools::Itertools;
let data = vec![(0, 1.), (1, 1.), (0, 2.), (0, 3.), (1, 3.), (1, 2.), (2, 2.)];
itertools::assert_equal(data.into_iter().dedup_by(|x, y| x.1 == y.1),
vec![(0, 1.), (0, 2.), (0, 3.), (1, 2.)]);
fn dedup_with_count(self) -> DedupWithCount<Self> where
Self: Sized,
fn dedup_with_count(self) -> DedupWithCount<Self> where
Self: Sized,
Remove duplicates from sections of consecutive identical elements, while keeping a count of how many repeated elements were present. If the iterator is sorted, all elements will be unique.
Iterator element type is (usize, Self::Item)
.
This iterator is fused.
use itertools::Itertools;
let data = vec!['a', 'a', 'b', 'c', 'c', 'b', 'b'];
itertools::assert_equal(data.into_iter().dedup_with_count(),
vec![(2, 'a'), (1, 'b'), (2, 'c'), (2, 'b')]);
fn dedup_by_with_count<Cmp>(self, cmp: Cmp) -> DedupByWithCount<Self, Cmp> where
Self: Sized,
Cmp: FnMut(&Self::Item, &Self::Item) -> bool,
fn dedup_by_with_count<Cmp>(self, cmp: Cmp) -> DedupByWithCount<Self, Cmp> where
Self: Sized,
Cmp: FnMut(&Self::Item, &Self::Item) -> bool,
Remove duplicates from sections of consecutive identical elements, while keeping a count of how many repeated elements were present. This will determine equality using a comparison function. If the iterator is sorted, all elements will be unique.
Iterator element type is (usize, Self::Item)
.
This iterator is fused.
use itertools::Itertools;
let data = vec![(0, 'a'), (1, 'a'), (0, 'b'), (0, 'c'), (1, 'c'), (1, 'b'), (2, 'b')];
itertools::assert_equal(data.into_iter().dedup_by_with_count(|x, y| x.1 == y.1),
vec![(2, (0, 'a')), (1, (0, 'b')), (2, (0, 'c')), (2, (1, 'b'))]);
fn duplicates(self) -> Duplicates<Self> where
Self: Sized,
Self::Item: Eq + Hash,
fn duplicates(self) -> Duplicates<Self> where
Self: Sized,
Self::Item: Eq + Hash,
Return an iterator adaptor that produces elements that appear more than once during the iteration. Duplicates are detected using hash and equality.
The iterator is stable, returning the duplicate items in the order in which they occur in the adapted iterator. Each duplicate item is returned exactly once. If an item appears more than twice, the second item is the item retained and the rest are discarded.
use itertools::Itertools;
let data = vec![10, 20, 30, 20, 40, 10, 50];
itertools::assert_equal(data.into_iter().duplicates(),
vec![20, 10]);
fn duplicates_by<V, F>(self, f: F) -> DuplicatesBy<Self, V, F> where
Self: Sized,
V: Eq + Hash,
F: FnMut(&Self::Item) -> V,
fn duplicates_by<V, F>(self, f: F) -> DuplicatesBy<Self, V, F> where
Self: Sized,
V: Eq + Hash,
F: FnMut(&Self::Item) -> V,
Return an iterator adaptor that produces elements that appear more than once during the iteration. Duplicates are detected using hash and equality.
Duplicates are detected by comparing the key they map to with the keying function f
by
hash and equality. The keys are stored in a hash map in the iterator.
The iterator is stable, returning the duplicate items in the order in which they occur in the adapted iterator. Each duplicate item is returned exactly once. If an item appears more than twice, the second item is the item retained and the rest are discarded.
use itertools::Itertools;
let data = vec!["a", "bb", "aa", "c", "ccc"];
itertools::assert_equal(data.into_iter().duplicates_by(|s| s.len()),
vec!["aa", "c"]);
Return an iterator adaptor that filters out elements that have already been produced once during the iteration. Duplicates are detected using hash and equality.
Clones of visited elements are stored in a hash set in the iterator.
The iterator is stable, returning the non-duplicate items in the order in which they occur in the adapted iterator. In a set of duplicate items, the first item encountered is the item retained.
use itertools::Itertools;
let data = vec![10, 20, 30, 20, 40, 10, 50];
itertools::assert_equal(data.into_iter().unique(),
vec![10, 20, 30, 40, 50]);
Return an iterator adaptor that filters out elements that have already been produced once during the iteration.
Duplicates are detected by comparing the key they map to
with the keying function f
by hash and equality.
The keys are stored in a hash set in the iterator.
The iterator is stable, returning the non-duplicate items in the order in which they occur in the adapted iterator. In a set of duplicate items, the first item encountered is the item retained.
use itertools::Itertools;
let data = vec!["a", "bb", "aa", "c", "ccc"];
itertools::assert_equal(data.into_iter().unique_by(|s| s.len()),
vec!["a", "bb", "ccc"]);
fn peeking_take_while<F>(&mut self, accept: F) -> PeekingTakeWhile<'_, Self, F>ⓘNotable traits for PeekingTakeWhile<'a, I, F>impl<'a, I, F> Iterator for PeekingTakeWhile<'a, I, F> where
I: PeekingNext,
F: FnMut(&I::Item) -> bool, type Item = I::Item;
where
Self: Sized + PeekingNext,
F: FnMut(&Self::Item) -> bool,
fn peeking_take_while<F>(&mut self, accept: F) -> PeekingTakeWhile<'_, Self, F>ⓘNotable traits for PeekingTakeWhile<'a, I, F>impl<'a, I, F> Iterator for PeekingTakeWhile<'a, I, F> where
I: PeekingNext,
F: FnMut(&I::Item) -> bool, type Item = I::Item;
where
Self: Sized + PeekingNext,
F: FnMut(&Self::Item) -> bool,
I: PeekingNext,
F: FnMut(&I::Item) -> bool, type Item = I::Item;
Return an iterator adaptor that borrows from this iterator and
takes items while the closure accept
returns true
.
This adaptor can only be used on iterators that implement PeekingNext
like .peekable()
, put_back
and a few other collection iterators.
The last and rejected element (first false
) is still available when
peeking_take_while
is done.
See also .take_while_ref()
which is a similar adaptor.
fn take_while_ref<F>(&mut self, accept: F) -> TakeWhileRef<'_, Self, F>ⓘNotable traits for TakeWhileRef<'a, I, F>impl<'a, I, F> Iterator for TakeWhileRef<'a, I, F> where
I: Iterator + Clone,
F: FnMut(&I::Item) -> bool, type Item = I::Item;
where
Self: Clone,
F: FnMut(&Self::Item) -> bool,
fn take_while_ref<F>(&mut self, accept: F) -> TakeWhileRef<'_, Self, F>ⓘNotable traits for TakeWhileRef<'a, I, F>impl<'a, I, F> Iterator for TakeWhileRef<'a, I, F> where
I: Iterator + Clone,
F: FnMut(&I::Item) -> bool, type Item = I::Item;
where
Self: Clone,
F: FnMut(&Self::Item) -> bool,
I: Iterator + Clone,
F: FnMut(&I::Item) -> bool, type Item = I::Item;
Return an iterator adaptor that borrows from a Clone
-able iterator
to only pick off elements while the predicate accept
returns true
.
It uses the Clone
trait to restore the original iterator so that the
last and rejected element (first false
) is still available when
take_while_ref
is done.
use itertools::Itertools;
let mut hexadecimals = "0123456789abcdef".chars();
let decimals = hexadecimals.take_while_ref(|c| c.is_numeric())
.collect::<String>();
assert_eq!(decimals, "0123456789");
assert_eq!(hexadecimals.next(), Some('a'));
Return an iterator adaptor that filters Option<A>
iterator elements
and produces A
. Stops on the first None
encountered.
Iterator element type is A
, the unwrapped element.
use itertools::Itertools;
// List all hexadecimal digits
itertools::assert_equal(
(0..).map(|i| std::char::from_digit(i, 16)).while_some(),
"0123456789abcdef".chars());
fn tuple_combinations<T>(self) -> TupleCombinations<Self, T>ⓘNotable traits for TupleCombinations<I, T>impl<I, T> Iterator for TupleCombinations<I, T> where
I: Iterator,
T: HasCombination<I>, type Item = T;
where
Self: Sized + Clone,
Self::Item: Clone,
T: HasCombination<Self>,
fn tuple_combinations<T>(self) -> TupleCombinations<Self, T>ⓘNotable traits for TupleCombinations<I, T>impl<I, T> Iterator for TupleCombinations<I, T> where
I: Iterator,
T: HasCombination<I>, type Item = T;
where
Self: Sized + Clone,
Self::Item: Clone,
T: HasCombination<Self>,
I: Iterator,
T: HasCombination<I>, type Item = T;
Return an iterator adaptor that iterates over the combinations of the elements from an iterator.
Iterator element can be any homogeneous tuple of type Self::Item
with
size up to 12.
use itertools::Itertools;
let mut v = Vec::new();
for (a, b) in (1..5).tuple_combinations() {
v.push((a, b));
}
assert_eq!(v, vec![(1, 2), (1, 3), (1, 4), (2, 3), (2, 4), (3, 4)]);
let mut it = (1..5).tuple_combinations();
assert_eq!(Some((1, 2, 3)), it.next());
assert_eq!(Some((1, 2, 4)), it.next());
assert_eq!(Some((1, 3, 4)), it.next());
assert_eq!(Some((2, 3, 4)), it.next());
assert_eq!(None, it.next());
// this requires a type hint
let it = (1..5).tuple_combinations::<(_, _, _)>();
itertools::assert_equal(it, vec![(1, 2, 3), (1, 2, 4), (1, 3, 4), (2, 3, 4)]);
// you can also specify the complete type
use itertools::TupleCombinations;
use std::ops::Range;
let it: TupleCombinations<Range<u32>, (u32, u32, u32)> = (1..5).tuple_combinations();
itertools::assert_equal(it, vec![(1, 2, 3), (1, 2, 4), (1, 3, 4), (2, 3, 4)]);
fn combinations(self, k: usize) -> Combinations<Self>ⓘNotable traits for Combinations<I>impl<I> Iterator for Combinations<I> where
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Sized,
Self::Item: Clone,
fn combinations(self, k: usize) -> Combinations<Self>ⓘNotable traits for Combinations<I>impl<I> Iterator for Combinations<I> where
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Sized,
Self::Item: Clone,
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
Return an iterator adaptor that iterates over the k
-length combinations of
the elements from an iterator.
Iterator element type is Vec<Self::Item>
. The iterator produces a new Vec per iteration,
and clones the iterator elements.
use itertools::Itertools;
let it = (1..5).combinations(3);
itertools::assert_equal(it, vec![
vec![1, 2, 3],
vec![1, 2, 4],
vec![1, 3, 4],
vec![2, 3, 4],
]);
Note: Combinations does not take into account the equality of the iterated values.
use itertools::Itertools;
let it = vec![1, 2, 2].into_iter().combinations(2);
itertools::assert_equal(it, vec![
vec![1, 2], // Note: these are the same
vec![1, 2], // Note: these are the same
vec![2, 2],
]);
fn combinations_with_replacement(
self,
k: usize
) -> CombinationsWithReplacement<Self>ⓘNotable traits for CombinationsWithReplacement<I>impl<I> Iterator for CombinationsWithReplacement<I> where
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Sized,
Self::Item: Clone,
fn combinations_with_replacement(
self,
k: usize
) -> CombinationsWithReplacement<Self>ⓘNotable traits for CombinationsWithReplacement<I>impl<I> Iterator for CombinationsWithReplacement<I> where
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Sized,
Self::Item: Clone,
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
Return an iterator that iterates over the k
-length combinations of
the elements from an iterator, with replacement.
Iterator element type is Vec<Self::Item>
. The iterator produces a new Vec per iteration,
and clones the iterator elements.
use itertools::Itertools;
let it = (1..4).combinations_with_replacement(2);
itertools::assert_equal(it, vec![
vec![1, 1],
vec![1, 2],
vec![1, 3],
vec![2, 2],
vec![2, 3],
vec![3, 3],
]);
fn permutations(self, k: usize) -> Permutations<Self>ⓘNotable traits for Permutations<I>impl<I> Iterator for Permutations<I> where
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Sized,
Self::Item: Clone,
fn permutations(self, k: usize) -> Permutations<Self>ⓘNotable traits for Permutations<I>impl<I> Iterator for Permutations<I> where
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
where
Self: Sized,
Self::Item: Clone,
I: Iterator,
I::Item: Clone, type Item = Vec<I::Item>;
Return an iterator adaptor that iterates over all k-permutations of the elements from an iterator.
Iterator element type is Vec<Self::Item>
with length k
. The iterator
produces a new Vec per iteration, and clones the iterator elements.
If k
is greater than the length of the input iterator, the resultant
iterator adaptor will be empty.
use itertools::Itertools;
let perms = (5..8).permutations(2);
itertools::assert_equal(perms, vec![
vec![5, 6],
vec![5, 7],
vec![6, 5],
vec![6, 7],
vec![7, 5],
vec![7, 6],
]);
Note: Permutations does not take into account the equality of the iterated values.
use itertools::Itertools;
let it = vec![2, 2].into_iter().permutations(2);
itertools::assert_equal(it, vec![
vec![2, 2], // Note: these are the same
vec![2, 2], // Note: these are the same
]);
Note: The source iterator is collected lazily, and will not be re-iterated if the permutations adaptor is completed and re-iterated.
Return an iterator that iterates through the powerset of the elements from an iterator.
Iterator element type is Vec<Self::Item>
. The iterator produces a new Vec
per iteration, and clones the iterator elements.
The powerset of a set contains all subsets including the empty set and the full input set. A powerset has length 2^n where n is the length of the input set.
Each Vec
produced by this iterator represents a subset of the elements
produced by the source iterator.
use itertools::Itertools;
let sets = (1..4).powerset().collect::<Vec<_>>();
itertools::assert_equal(sets, vec![
vec![],
vec![1],
vec![2],
vec![3],
vec![1, 2],
vec![1, 3],
vec![2, 3],
vec![1, 2, 3],
]);
Return an iterator adaptor that pads the sequence to a minimum length of
min
by filling missing elements using a closure f
.
Iterator element type is Self::Item
.
use itertools::Itertools;
let it = (0..5).pad_using(10, |i| 2*i);
itertools::assert_equal(it, vec![0, 1, 2, 3, 4, 10, 12, 14, 16, 18]);
let it = (0..10).pad_using(5, |i| 2*i);
itertools::assert_equal(it, vec![0, 1, 2, 3, 4, 5, 6, 7, 8, 9]);
let it = (0..5).pad_using(10, |i| 2*i).rev();
itertools::assert_equal(it, vec![18, 16, 14, 12, 10, 4, 3, 2, 1, 0]);
fn with_position(self) -> WithPosition<Self>ⓘNotable traits for WithPosition<I>impl<I: Iterator> Iterator for WithPosition<I> type Item = Position<I::Item>;
where
Self: Sized,
fn with_position(self) -> WithPosition<Self>ⓘNotable traits for WithPosition<I>impl<I: Iterator> Iterator for WithPosition<I> type Item = Position<I::Item>;
where
Self: Sized,
Return an iterator adaptor that wraps each element in a Position
to
ease special-case handling of the first or last elements.
Iterator element type is
Position<Self::Item>
use itertools::{Itertools, Position};
let it = (0..4).with_position();
itertools::assert_equal(it,
vec![Position::First(0),
Position::Middle(1),
Position::Middle(2),
Position::Last(3)]);
let it = (0..1).with_position();
itertools::assert_equal(it, vec![Position::Only(0)]);
Return an iterator adaptor that yields the indices of all elements satisfying a predicate, counted from the start of the iterator.
Equivalent to iter.enumerate().filter(|(_, v)| predicate(v)).map(|(i, _)| i)
.
use itertools::Itertools;
let data = vec![1, 2, 3, 3, 4, 6, 7, 9];
itertools::assert_equal(data.iter().positions(|v| v % 2 == 0), vec![1, 4, 5]);
itertools::assert_equal(data.iter().positions(|v| v % 2 == 1).rev(), vec![7, 6, 3, 2, 0]);
Return an iterator adaptor that applies a mutating function to each element before yielding it.
use itertools::Itertools;
let input = vec![vec![1], vec![3, 2, 1]];
let it = input.into_iter().update(|mut v| v.push(0));
itertools::assert_equal(it, vec![vec![1, 0], vec![3, 2, 1, 0]]);
fn next_tuple<T>(&mut self) -> Option<T> where
Self: Sized + Iterator<Item = T::Item>,
T: HomogeneousTuple,
fn next_tuple<T>(&mut self) -> Option<T> where
Self: Sized + Iterator<Item = T::Item>,
T: HomogeneousTuple,
Advances the iterator and returns the next items grouped in a tuple of a specific size (up to 12).
If there are enough elements to be grouped in a tuple, then the tuple is
returned inside Some
, otherwise None
is returned.
use itertools::Itertools;
let mut iter = 1..5;
assert_eq!(Some((1, 2)), iter.next_tuple());
fn collect_tuple<T>(self) -> Option<T> where
Self: Sized + Iterator<Item = T::Item>,
T: HomogeneousTuple,
fn collect_tuple<T>(self) -> Option<T> where
Self: Sized + Iterator<Item = T::Item>,
T: HomogeneousTuple,
Collects all items from the iterator into a tuple of a specific size (up to 12).
If the number of elements inside the iterator is exactly equal to
the tuple size, then the tuple is returned inside Some
, otherwise
None
is returned.
use itertools::Itertools;
let iter = 1..3;
if let Some((x, y)) = iter.collect_tuple() {
assert_eq!((x, y), (1, 2))
} else {
panic!("Expected two elements")
}
Find the position and value of the first element satisfying a predicate.
The iterator is not advanced past the first element found.
use itertools::Itertools;
let text = "Hα";
assert_eq!(text.chars().find_position(|ch| ch.is_lowercase()), Some((1, 'α')));
Find the value of the first element satisfying a predicate or return the last element, if any.
The iterator is not advanced past the first element found.
use itertools::Itertools;
let numbers = [1, 2, 3, 4];
assert_eq!(numbers.iter().find_or_last(|&&x| x > 5), Some(&4));
assert_eq!(numbers.iter().find_or_last(|&&x| x > 2), Some(&3));
assert_eq!(std::iter::empty::<i32>().find_or_last(|&x| x > 5), None);
Find the value of the first element satisfying a predicate or return the first element, if any.
The iterator is not advanced past the first element found.
use itertools::Itertools;
let numbers = [1, 2, 3, 4];
assert_eq!(numbers.iter().find_or_first(|&&x| x > 5), Some(&1));
assert_eq!(numbers.iter().find_or_first(|&&x| x > 2), Some(&3));
assert_eq!(std::iter::empty::<i32>().find_or_first(|&x| x > 5), None);
Returns true
if the given item is present in this iterator.
This method is short-circuiting. If the given item is present in this iterator, this method will consume the iterator up-to-and-including the item. If the given item is not present in this iterator, the iterator will be exhausted.
use itertools::Itertools;
#[derive(PartialEq, Debug)]
enum Enum { A, B, C, D, E, }
let mut iter = vec![Enum::A, Enum::B, Enum::C, Enum::D].into_iter();
// search `iter` for `B`
assert_eq!(iter.contains(&Enum::B), true);
// `B` was found, so the iterator now rests at the item after `B` (i.e, `C`).
assert_eq!(iter.next(), Some(Enum::C));
// search `iter` for `E`
assert_eq!(iter.contains(&Enum::E), false);
// `E` wasn't found, so `iter` is now exhausted
assert_eq!(iter.next(), None);
Check whether all elements compare equal.
Empty iterators are considered to have equal elements:
use itertools::Itertools;
let data = vec![1, 1, 1, 2, 2, 3, 3, 3, 4, 5, 5];
assert!(!data.iter().all_equal());
assert!(data[0..3].iter().all_equal());
assert!(data[3..5].iter().all_equal());
assert!(data[5..8].iter().all_equal());
let data : Option<usize> = None;
assert!(data.into_iter().all_equal());
Check whether all elements are unique (non equal).
Empty iterators are considered to have unique elements:
use itertools::Itertools;
let data = vec![1, 2, 3, 4, 1, 5];
assert!(!data.iter().all_unique());
assert!(data[0..4].iter().all_unique());
assert!(data[1..6].iter().all_unique());
let data : Option<usize> = None;
assert!(data.into_iter().all_unique());
Consume the first n
elements from the iterator eagerly,
and return the same iterator again.
It works similarly to .skip( n
) except it is eager and
preserves the iterator type.
use itertools::Itertools;
let mut iter = "αβγ".chars().dropping(2);
itertools::assert_equal(iter, "γ".chars());
Fusing notes: if the iterator is exhausted by dropping,
the result of calling .next()
again depends on the iterator implementation.
fn dropping_back(self, n: usize) -> Self where
Self: Sized,
Self: DoubleEndedIterator,
fn dropping_back(self, n: usize) -> Self where
Self: Sized,
Self: DoubleEndedIterator,
Consume the last n
elements from the iterator eagerly,
and return the same iterator again.
This is only possible on double ended iterators. n
may be
larger than the number of elements.
Note: This method is eager, dropping the back elements immediately and preserves the iterator type.
use itertools::Itertools;
let init = vec![0, 3, 6, 9].into_iter().dropping_back(1);
itertools::assert_equal(init, vec![0, 3, 6]);
Use .for_each() instead
Run the closure f
eagerly on each element of the iterator.
Consumes the iterator until its end.
use std::sync::mpsc::channel;
use itertools::Itertools;
let (tx, rx) = channel();
// use .foreach() to apply a function to each value -- sending it
(0..5).map(|x| x * 2 + 1).foreach(|x| { tx.send(x).unwrap(); } );
drop(tx);
itertools::assert_equal(rx.iter(), vec![1, 3, 5, 7, 9]);
Combine all an iterator’s elements into one element by using Extend
.
This combinator will extend the first item with each of the rest of the
items of the iterator. If the iterator is empty, the default value of
I::Item
is returned.
use itertools::Itertools;
let input = vec![vec![1], vec![2, 3], vec![4, 5, 6]];
assert_eq!(input.into_iter().concat(),
vec![1, 2, 3, 4, 5, 6]);
fn collect_vec(self) -> Vec<Self::Item> where
Self: Sized,
fn collect_vec(self) -> Vec<Self::Item> where
Self: Sized,
.collect_vec()
is simply a type specialization of Iterator::collect
,
for convenience.
fn try_collect<T, U, E>(self) -> Result<U, E> where
Self: Sized + Iterator<Item = Result<T, E>>,
Result<U, E>: FromIterator<Result<T, E>>,
fn try_collect<T, U, E>(self) -> Result<U, E> where
Self: Sized + Iterator<Item = Result<T, E>>,
Result<U, E>: FromIterator<Result<T, E>>,
.try_collect()
is more convenient way of writing
.collect::<Result<_, _>>()
Example
use std::{fs, io};
use itertools::Itertools;
fn process_dir_entries(entries: &[fs::DirEntry]) {
// ...
}
fn do_stuff() -> std::io::Result<()> {
let entries: Vec<_> = fs::read_dir(".")?.try_collect()?;
process_dir_entries(&entries);
Ok(())
}
Assign to each reference in self
from the from
iterator,
stopping at the shortest of the two iterators.
The from
iterator is queried for its next element before the self
iterator, and if either is exhausted the method is done.
Return the number of elements written.
use itertools::Itertools;
let mut xs = [0; 4];
xs.iter_mut().set_from(1..);
assert_eq!(xs, [1, 2, 3, 4]);
Combine all iterator elements into one String, separated by sep
.
Use the Display
implementation of each element.
use itertools::Itertools;
assert_eq!(["a", "b", "c"].iter().join(", "), "a, b, c");
assert_eq!([1, 2, 3].iter().join(", "), "1, 2, 3");
Format all iterator elements, separated by sep
.
All elements are formatted (any formatting trait)
with sep
inserted between each element.
Panics if the formatter helper is formatted more than once.
use itertools::Itertools;
let data = [1.1, 2.71828, -3.];
assert_eq!(
format!("{:.2}", data.iter().format(", ")),
"1.10, 2.72, -3.00");
Format all iterator elements, separated by sep
.
This is a customizable version of .format()
.
The supplied closure format
is called once per iterator element,
with two arguments: the element and a callback that takes a
&Display
value, i.e. any reference to type that implements Display
.
Using &format_args!(...)
is the most versatile way to apply custom
element formatting. The callback can be called multiple times if needed.
Panics if the formatter helper is formatted more than once.
use itertools::Itertools;
let data = [1.1, 2.71828, -3.];
let data_formatter = data.iter().format_with(", ", |elt, f| f(&format_args!("{:.2}", elt)));
assert_eq!(format!("{}", data_formatter),
"1.10, 2.72, -3.00");
// .format_with() is recursively composable
let matrix = [[1., 2., 3.],
[4., 5., 6.]];
let matrix_formatter = matrix.iter().format_with("\n", |row, f| {
f(&row.iter().format_with(", ", |elt, g| g(&elt)))
});
assert_eq!(format!("{}", matrix_formatter),
"1, 2, 3\n4, 5, 6");
Fold Result
values from an iterator.
Only Ok
values are folded. If no error is encountered, the folded
value is returned inside Ok
. Otherwise, the operation terminates
and returns the first Err
value it encounters. No iterator elements are
consumed after the first error.
The first accumulator value is the start
parameter.
Each iteration passes the accumulator value and the next value inside Ok
to the fold function f
and its return value becomes the new accumulator value.
For example the sequence Ok(1), Ok(2), Ok(3) will result in a computation like this:
let mut accum = start;
accum = f(accum, 1);
accum = f(accum, 2);
accum = f(accum, 3);
With a start
value of 0 and an addition as folding function,
this effectively results in ((0 + 1) + 2) + 3
use std::ops::Add;
use itertools::Itertools;
let values = [1, 2, -2, -1, 2, 1];
assert_eq!(
values.iter()
.map(Ok::<_, ()>)
.fold_ok(0, Add::add),
Ok(3)
);
assert!(
values.iter()
.map(|&x| if x >= 0 { Ok(x) } else { Err("Negative number") })
.fold_ok(0, Add::add)
.is_err()
);
Fold Option
values from an iterator.
Only Some
values are folded. If no None
is encountered, the folded
value is returned inside Some
. Otherwise, the operation terminates
and returns None
. No iterator elements are consumed after the None
.
This is the Option
equivalent to fold_ok
.
use std::ops::Add;
use itertools::Itertools;
let mut values = vec![Some(1), Some(2), Some(-2)].into_iter();
assert_eq!(values.fold_options(5, Add::add), Some(5 + 1 + 2 - 2));
let mut more_values = vec![Some(2), None, Some(0)].into_iter();
assert!(more_values.fold_options(0, Add::add).is_none());
assert_eq!(more_values.next().unwrap(), Some(0));
Use Iterator::reduce
instead
Accumulator of the elements in the iterator.
Like .fold()
, without a base case. If the iterator is
empty, return None
. With just one element, return it.
Otherwise elements are accumulated in sequence using the closure f
.
use itertools::Itertools;
assert_eq!((0..10).fold1(|x, y| x + y).unwrap_or(0), 45);
assert_eq!((0..0).fold1(|x, y| x * y), None);
Accumulate the elements in the iterator in a tree-like manner.
You can think of it as, while there’s more than one item, repeatedly combining adjacent items. It does so in bottom-up-merge-sort order, however, so that it needs only logarithmic stack space.
This produces a call tree like the following (where the calls under an item are done after reading that item):
1 2 3 4 5 6 7
│ │ │ │ │ │ │
└─f └─f └─f │
│ │ │ │
└───f └─f
│ │
└─────f
Which, for non-associative functions, will typically produce a different
result than the linear call tree used by fold1
:
1 2 3 4 5 6 7
│ │ │ │ │ │ │
└─f─f─f─f─f─f
If f
is associative, prefer the normal fold1
instead.
use itertools::Itertools;
// The same tree as above
let num_strings = (1..8).map(|x| x.to_string());
assert_eq!(num_strings.tree_fold1(|x, y| format!("f({}, {})", x, y)),
Some(String::from("f(f(f(1, 2), f(3, 4)), f(f(5, 6), 7))")));
// Like fold1, an empty iterator produces None
assert_eq!((0..0).tree_fold1(|x, y| x * y), None);
// tree_fold1 matches fold1 for associative operations...
assert_eq!((0..10).tree_fold1(|x, y| x + y),
(0..10).fold1(|x, y| x + y));
// ...but not for non-associative ones
assert_ne!((0..10).tree_fold1(|x, y| x - y),
(0..10).fold1(|x, y| x - y));
An iterator method that applies a function, producing a single, final value.
fold_while()
is basically equivalent to Iterator::fold
but with additional support for
early exit via short-circuiting.
use itertools::Itertools;
use itertools::FoldWhile::{Continue, Done};
let numbers = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10];
let mut result = 0;
// for loop:
for i in &numbers {
if *i > 5 {
break;
}
result = result + i;
}
// fold:
let result2 = numbers.iter().fold(0, |acc, x| {
if *x > 5 { acc } else { acc + x }
});
// fold_while:
let result3 = numbers.iter().fold_while(0, |acc, x| {
if *x > 5 { Done(acc) } else { Continue(acc + x) }
}).into_inner();
// they're the same
assert_eq!(result, result2);
assert_eq!(result2, result3);
The big difference between the computations of result2
and result3
is that while
fold()
called the provided closure for every item of the callee iterator,
fold_while()
actually stopped iterating as soon as it encountered Fold::Done(_)
.
Iterate over the entire iterator and add all the elements.
An empty iterator returns None
, otherwise Some(sum)
.
Panics
When calling sum1()
and a primitive integer type is being returned, this
method will panic if the computation overflows and debug assertions are
enabled.
Examples
use itertools::Itertools;
let empty_sum = (1..1).sum1::<i32>();
assert_eq!(empty_sum, None);
let nonempty_sum = (1..11).sum1::<i32>();
assert_eq!(nonempty_sum, Some(55));
Iterate over the entire iterator and multiply all the elements.
An empty iterator returns None
, otherwise Some(product)
.
Panics
When calling product1()
and a primitive integer type is being returned,
method will panic if the computation overflows and debug assertions are
enabled.
Examples
use itertools::Itertools;
let empty_product = (1..1).product1::<i32>();
assert_eq!(empty_product, None);
let nonempty_product = (1..11).product1::<i32>();
assert_eq!(nonempty_product, Some(3628800));
Sort all iterator elements into a new iterator in ascending order.
Note: This consumes the entire iterator, uses the
slice::sort_unstable
method and returns the result as a new
iterator that owns its elements.
The sorted iterator, if directly collected to a Vec
, is converted
without any extra copying or allocation cost.
use itertools::Itertools;
// sort the letters of the text in ascending order
let text = "bdacfe";
itertools::assert_equal(text.chars().sorted_unstable(),
"abcdef".chars());
Sort all iterator elements into a new iterator in ascending order.
Note: This consumes the entire iterator, uses the
slice::sort_unstable_by
method and returns the result as a new
iterator that owns its elements.
The sorted iterator, if directly collected to a Vec
, is converted
without any extra copying or allocation cost.
use itertools::Itertools;
// sort people in descending order by age
let people = vec![("Jane", 20), ("John", 18), ("Jill", 30), ("Jack", 27)];
let oldest_people_first = people
.into_iter()
.sorted_unstable_by(|a, b| Ord::cmp(&b.1, &a.1))
.map(|(person, _age)| person);
itertools::assert_equal(oldest_people_first,
vec!["Jill", "Jack", "Jane", "John"]);
Sort all iterator elements into a new iterator in ascending order.
Note: This consumes the entire iterator, uses the
slice::sort_unstable_by_key
method and returns the result as a new
iterator that owns its elements.
The sorted iterator, if directly collected to a Vec
, is converted
without any extra copying or allocation cost.
use itertools::Itertools;
// sort people in descending order by age
let people = vec![("Jane", 20), ("John", 18), ("Jill", 30), ("Jack", 27)];
let oldest_people_first = people
.into_iter()
.sorted_unstable_by_key(|x| -x.1)
.map(|(person, _age)| person);
itertools::assert_equal(oldest_people_first,
vec!["Jill", "Jack", "Jane", "John"]);
Sort all iterator elements into a new iterator in ascending order.
Note: This consumes the entire iterator, uses the
slice::sort
method and returns the result as a new
iterator that owns its elements.
The sorted iterator, if directly collected to a Vec
, is converted
without any extra copying or allocation cost.
use itertools::Itertools;
// sort the letters of the text in ascending order
let text = "bdacfe";
itertools::assert_equal(text.chars().sorted(),
"abcdef".chars());
Sort all iterator elements into a new iterator in ascending order.
Note: This consumes the entire iterator, uses the
slice::sort_by
method and returns the result as a new
iterator that owns its elements.
The sorted iterator, if directly collected to a Vec
, is converted
without any extra copying or allocation cost.
use itertools::Itertools;
// sort people in descending order by age
let people = vec![("Jane", 20), ("John", 18), ("Jill", 30), ("Jack", 27)];
let oldest_people_first = people
.into_iter()
.sorted_by(|a, b| Ord::cmp(&b.1, &a.1))
.map(|(person, _age)| person);
itertools::assert_equal(oldest_people_first,
vec!["Jill", "Jack", "Jane", "John"]);
Sort all iterator elements into a new iterator in ascending order.
Note: This consumes the entire iterator, uses the
slice::sort_by_key
method and returns the result as a new
iterator that owns its elements.
The sorted iterator, if directly collected to a Vec
, is converted
without any extra copying or allocation cost.
use itertools::Itertools;
// sort people in descending order by age
let people = vec![("Jane", 20), ("John", 18), ("Jill", 30), ("Jack", 27)];
let oldest_people_first = people
.into_iter()
.sorted_by_key(|x| -x.1)
.map(|(person, _age)| person);
itertools::assert_equal(oldest_people_first,
vec!["Jill", "Jack", "Jane", "John"]);
Sort all iterator elements into a new iterator in ascending order. The key function is called exactly once per key.
Note: This consumes the entire iterator, uses the
slice::sort_by_cached_key
method and returns the result as a new
iterator that owns its elements.
The sorted iterator, if directly collected to a Vec
, is converted
without any extra copying or allocation cost.
use itertools::Itertools;
// sort people in descending order by age
let people = vec![("Jane", 20), ("John", 18), ("Jill", 30), ("Jack", 27)];
let oldest_people_first = people
.into_iter()
.sorted_by_cached_key(|x| -x.1)
.map(|(person, _age)| person);
itertools::assert_equal(oldest_people_first,
vec!["Jill", "Jack", "Jane", "John"]);
Sort the k smallest elements into a new iterator, in ascending order.
Note: This consumes the entire iterator, and returns the result
as a new iterator that owns its elements. If the input contains
less than k elements, the result is equivalent to self.sorted()
.
This is guaranteed to use k * sizeof(Self::Item) + O(1)
memory
and O(n log k)
time, with n
the number of elements in the input.
The sorted iterator, if directly collected to a Vec
, is converted
without any extra copying or allocation cost.
Note: This is functionally-equivalent to self.sorted().take(k)
but much more efficient.
use itertools::Itertools;
// A random permutation of 0..15
let numbers = vec![6, 9, 1, 14, 0, 4, 8, 7, 11, 2, 10, 3, 13, 12, 5];
let five_smallest = numbers
.into_iter()
.k_smallest(5);
itertools::assert_equal(five_smallest, 0..5);
Collect all iterator elements into one of two
partitions. Unlike Iterator::partition
, each partition may
have a distinct type.
use itertools::{Itertools, Either};
let successes_and_failures = vec![Ok(1), Err(false), Err(true), Ok(2)];
let (successes, failures): (Vec<_>, Vec<_>) = successes_and_failures
.into_iter()
.partition_map(|r| {
match r {
Ok(v) => Either::Left(v),
Err(v) => Either::Right(v),
}
});
assert_eq!(successes, [1, 2]);
assert_eq!(failures, [false, true]);
Partition a sequence of Result
s into one list of all the Ok
elements
and another list of all the Err
elements.
use itertools::Itertools;
let successes_and_failures = vec![Ok(1), Err(false), Err(true), Ok(2)];
let (successes, failures): (Vec<_>, Vec<_>) = successes_and_failures
.into_iter()
.partition_result();
assert_eq!(successes, [1, 2]);
assert_eq!(failures, [false, true]);
Return a HashMap
of keys mapped to Vec
s of values. Keys and values
are taken from (Key, Value)
tuple pairs yielded by the input iterator.
Essentially a shorthand for .into_grouping_map().collect::<Vec<_>>()
.
use itertools::Itertools;
let data = vec![(0, 10), (2, 12), (3, 13), (0, 20), (3, 33), (2, 42)];
let lookup = data.into_iter().into_group_map();
assert_eq!(lookup[&0], vec![10, 20]);
assert_eq!(lookup.get(&1), None);
assert_eq!(lookup[&2], vec![12, 42]);
assert_eq!(lookup[&3], vec![13, 33]);
Return an Iterator
on a HashMap
. Keys mapped to Vec
s of values. The key is specified
in the closure.
Essentially a shorthand for .into_grouping_map_by(f).collect::<Vec<_>>()
.
use itertools::Itertools;
use std::collections::HashMap;
let data = vec![(0, 10), (2, 12), (3, 13), (0, 20), (3, 33), (2, 42)];
let lookup: HashMap<u32,Vec<(u32, u32)>> =
data.clone().into_iter().into_group_map_by(|a| a.0);
assert_eq!(lookup[&0], vec![(0,10),(0,20)]);
assert_eq!(lookup.get(&1), None);
assert_eq!(lookup[&2], vec![(2,12), (2,42)]);
assert_eq!(lookup[&3], vec![(3,13), (3,33)]);
assert_eq!(
data.into_iter()
.into_group_map_by(|x| x.0)
.into_iter()
.map(|(key, values)| (key, values.into_iter().fold(0,|acc, (_,v)| acc + v )))
.collect::<HashMap<u32,u32>>()[&0],
30,
);
fn into_grouping_map<K, V>(self) -> GroupingMap<Self> where
Self: Iterator<Item = (K, V)> + Sized,
K: Hash + Eq,
fn into_grouping_map<K, V>(self) -> GroupingMap<Self> where
Self: Iterator<Item = (K, V)> + Sized,
K: Hash + Eq,
Constructs a GroupingMap
to be used later with one of the efficient
group-and-fold operations it allows to perform.
The input iterator must yield item in the form of (K, V)
where the
value of type K
will be used as key to identify the groups and the
value of type V
as value for the folding operation.
See GroupingMap
for more informations
on what operations are available.
fn into_grouping_map_by<K, V, F>(self, key_mapper: F) -> GroupingMapBy<Self, F> where
Self: Iterator<Item = V> + Sized,
K: Hash + Eq,
F: FnMut(&V) -> K,
fn into_grouping_map_by<K, V, F>(self, key_mapper: F) -> GroupingMapBy<Self, F> where
Self: Iterator<Item = V> + Sized,
K: Hash + Eq,
F: FnMut(&V) -> K,
Constructs a GroupingMap
to be used later with one of the efficient
group-and-fold operations it allows to perform.
The values from this iterator will be used as values for the folding operation
while the keys will be obtained from the values by calling key_mapper
.
See GroupingMap
for more informations
on what operations are available.
fn minmax(self) -> MinMaxResult<Self::Item> where
Self: Sized,
Self::Item: PartialOrd,
fn minmax(self) -> MinMaxResult<Self::Item> where
Self: Sized,
Self::Item: PartialOrd,
Return the minimum and maximum elements in the iterator.
The return type MinMaxResult
is an enum of three variants:
NoElements
if the iterator is empty.OneElement(x)
if the iterator has exactly one element.MinMax(x, y)
is returned otherwise, wherex <= y
. Two values are equal if and only if there is more than one element in the iterator and all elements are equal.
On an iterator of length n
, minmax
does 1.5 * n
comparisons,
and so is faster than calling min
and max
separately which does
2 * n
comparisons.
Examples
use itertools::Itertools;
use itertools::MinMaxResult::{NoElements, OneElement, MinMax};
let a: [i32; 0] = [];
assert_eq!(a.iter().minmax(), NoElements);
let a = [1];
assert_eq!(a.iter().minmax(), OneElement(&1));
let a = [1, 2, 3, 4, 5];
assert_eq!(a.iter().minmax(), MinMax(&1, &5));
let a = [1, 1, 1, 1];
assert_eq!(a.iter().minmax(), MinMax(&1, &1));
The elements can be floats but no particular result is guaranteed if an element is NaN.
fn minmax_by_key<K, F>(self, key: F) -> MinMaxResult<Self::Item> where
Self: Sized,
K: PartialOrd,
F: FnMut(&Self::Item) -> K,
fn minmax_by_key<K, F>(self, key: F) -> MinMaxResult<Self::Item> where
Self: Sized,
K: PartialOrd,
F: FnMut(&Self::Item) -> K,
Return the minimum and maximum element of an iterator, as determined by the specified function.
The return value is a variant of MinMaxResult
like for .minmax()
.
For the minimum, the first minimal element is returned. For the maximum,
the last maximal element wins. This matches the behavior of the standard
Iterator::min
and Iterator::max
methods.
The keys can be floats but no particular result is guaranteed if a key is NaN.
Return the minimum and maximum element of an iterator, as determined by the specified comparison function.
The return value is a variant of MinMaxResult
like for .minmax()
.
For the minimum, the first minimal element is returned. For the maximum,
the last maximal element wins. This matches the behavior of the standard
Iterator::min
and Iterator::max
methods.
Return the position of the maximum element in the iterator.
If several elements are equally maximum, the position of the last of them is returned.
Examples
use itertools::Itertools;
let a: [i32; 0] = [];
assert_eq!(a.iter().position_max(), None);
let a = [-3, 0, 1, 5, -10];
assert_eq!(a.iter().position_max(), Some(3));
let a = [1, 1, -1, -1];
assert_eq!(a.iter().position_max(), Some(1));
Return the position of the maximum element in the iterator, as determined by the specified function.
If several elements are equally maximum, the position of the last of them is returned.
Examples
use itertools::Itertools;
let a: [i32; 0] = [];
assert_eq!(a.iter().position_max_by_key(|x| x.abs()), None);
let a = [-3_i32, 0, 1, 5, -10];
assert_eq!(a.iter().position_max_by_key(|x| x.abs()), Some(4));
let a = [1_i32, 1, -1, -1];
assert_eq!(a.iter().position_max_by_key(|x| x.abs()), Some(3));
Return the position of the maximum element in the iterator, as determined by the specified comparison function.
If several elements are equally maximum, the position of the last of them is returned.
Examples
use itertools::Itertools;
let a: [i32; 0] = [];
assert_eq!(a.iter().position_max_by(|x, y| x.cmp(y)), None);
let a = [-3_i32, 0, 1, 5, -10];
assert_eq!(a.iter().position_max_by(|x, y| x.cmp(y)), Some(3));
let a = [1_i32, 1, -1, -1];
assert_eq!(a.iter().position_max_by(|x, y| x.cmp(y)), Some(1));
Return the position of the minimum element in the iterator.
If several elements are equally minimum, the position of the first of them is returned.
Examples
use itertools::Itertools;
let a: [i32; 0] = [];
assert_eq!(a.iter().position_min(), None);
let a = [-3, 0, 1, 5, -10];
assert_eq!(a.iter().position_min(), Some(4));
let a = [1, 1, -1, -1];
assert_eq!(a.iter().position_min(), Some(2));
Return the position of the minimum element in the iterator, as determined by the specified function.
If several elements are equally minimum, the position of the first of them is returned.
Examples
use itertools::Itertools;
let a: [i32; 0] = [];
assert_eq!(a.iter().position_min_by_key(|x| x.abs()), None);
let a = [-3_i32, 0, 1, 5, -10];
assert_eq!(a.iter().position_min_by_key(|x| x.abs()), Some(1));
let a = [1_i32, 1, -1, -1];
assert_eq!(a.iter().position_min_by_key(|x| x.abs()), Some(0));
Return the position of the minimum element in the iterator, as determined by the specified comparison function.
If several elements are equally minimum, the position of the first of them is returned.
Examples
use itertools::Itertools;
let a: [i32; 0] = [];
assert_eq!(a.iter().position_min_by(|x, y| x.cmp(y)), None);
let a = [-3_i32, 0, 1, 5, -10];
assert_eq!(a.iter().position_min_by(|x, y| x.cmp(y)), Some(4));
let a = [1_i32, 1, -1, -1];
assert_eq!(a.iter().position_min_by(|x, y| x.cmp(y)), Some(2));
fn position_minmax(self) -> MinMaxResult<usize> where
Self: Sized,
Self::Item: PartialOrd,
fn position_minmax(self) -> MinMaxResult<usize> where
Self: Sized,
Self::Item: PartialOrd,
Return the positions of the minimum and maximum elements in the iterator.
The return type MinMaxResult
is an enum of three variants:
NoElements
if the iterator is empty.OneElement(xpos)
if the iterator has exactly one element.MinMax(xpos, ypos)
is returned otherwise, where the element atxpos
≤ the element atypos
. While the referenced elements themselves may be equal,xpos
cannot be equal toypos
.
On an iterator of length n
, position_minmax
does 1.5 * n
comparisons, and so is faster than calling positon_min
and
position_max
separately which does 2 * n
comparisons.
For the minimum, if several elements are equally minimum, the position of the first of them is returned. For the maximum, if several elements are equally maximum, the position of the last of them is returned.
The elements can be floats but no particular result is guaranteed if an element is NaN.
Examples
use itertools::Itertools;
use itertools::MinMaxResult::{NoElements, OneElement, MinMax};
let a: [i32; 0] = [];
assert_eq!(a.iter().position_minmax(), NoElements);
let a = [10];
assert_eq!(a.iter().position_minmax(), OneElement(0));
let a = [-3, 0, 1, 5, -10];
assert_eq!(a.iter().position_minmax(), MinMax(4, 3));
let a = [1, 1, -1, -1];
assert_eq!(a.iter().position_minmax(), MinMax(2, 1));
fn position_minmax_by_key<K, F>(self, key: F) -> MinMaxResult<usize> where
Self: Sized,
K: PartialOrd,
F: FnMut(&Self::Item) -> K,
fn position_minmax_by_key<K, F>(self, key: F) -> MinMaxResult<usize> where
Self: Sized,
K: PartialOrd,
F: FnMut(&Self::Item) -> K,
Return the postions of the minimum and maximum elements of an iterator, as determined by the specified function.
The return value is a variant of MinMaxResult
like for
position_minmax
.
For the minimum, if several elements are equally minimum, the position of the first of them is returned. For the maximum, if several elements are equally maximum, the position of the last of them is returned.
The keys can be floats but no particular result is guaranteed if a key is NaN.
Examples
use itertools::Itertools;
use itertools::MinMaxResult::{NoElements, OneElement, MinMax};
let a: [i32; 0] = [];
assert_eq!(a.iter().position_minmax_by_key(|x| x.abs()), NoElements);
let a = [10_i32];
assert_eq!(a.iter().position_minmax_by_key(|x| x.abs()), OneElement(0));
let a = [-3_i32, 0, 1, 5, -10];
assert_eq!(a.iter().position_minmax_by_key(|x| x.abs()), MinMax(1, 4));
let a = [1_i32, 1, -1, -1];
assert_eq!(a.iter().position_minmax_by_key(|x| x.abs()), MinMax(0, 3));
fn position_minmax_by<F>(self, compare: F) -> MinMaxResult<usize> where
Self: Sized,
F: FnMut(&Self::Item, &Self::Item) -> Ordering,
fn position_minmax_by<F>(self, compare: F) -> MinMaxResult<usize> where
Self: Sized,
F: FnMut(&Self::Item, &Self::Item) -> Ordering,
Return the postions of the minimum and maximum elements of an iterator, as determined by the specified comparison function.
The return value is a variant of MinMaxResult
like for
position_minmax
.
For the minimum, if several elements are equally minimum, the position of the first of them is returned. For the maximum, if several elements are equally maximum, the position of the last of them is returned.
Examples
use itertools::Itertools;
use itertools::MinMaxResult::{NoElements, OneElement, MinMax};
let a: [i32; 0] = [];
assert_eq!(a.iter().position_minmax_by(|x, y| x.cmp(y)), NoElements);
let a = [10_i32];
assert_eq!(a.iter().position_minmax_by(|x, y| x.cmp(y)), OneElement(0));
let a = [-3_i32, 0, 1, 5, -10];
assert_eq!(a.iter().position_minmax_by(|x, y| x.cmp(y)), MinMax(4, 3));
let a = [1_i32, 1, -1, -1];
assert_eq!(a.iter().position_minmax_by(|x, y| x.cmp(y)), MinMax(2, 1));
fn exactly_one(self) -> Result<Self::Item, ExactlyOneError<Self>> where
Self: Sized,
fn exactly_one(self) -> Result<Self::Item, ExactlyOneError<Self>> where
Self: Sized,
If the iterator yields exactly one element, that element will be returned, otherwise an error will be returned containing an iterator that has the same output as the input iterator.
This provides an additional layer of validation over just calling Iterator::next()
.
If your assumption that there should only be one element yielded is false this provides
the opportunity to detect and handle that, preventing errors at a distance.
Examples
use itertools::Itertools;
assert_eq!((0..10).filter(|&x| x == 2).exactly_one().unwrap(), 2);
assert!((0..10).filter(|&x| x > 1 && x < 4).exactly_one().unwrap_err().eq(2..4));
assert!((0..10).filter(|&x| x > 1 && x < 5).exactly_one().unwrap_err().eq(2..5));
assert!((0..10).filter(|&_| false).exactly_one().unwrap_err().eq(0..0));
fn at_most_one(self) -> Result<Option<Self::Item>, ExactlyOneError<Self>> where
Self: Sized,
fn at_most_one(self) -> Result<Option<Self::Item>, ExactlyOneError<Self>> where
Self: Sized,
If the iterator yields no elements, Ok(None) will be returned. If the iterator yields exactly one element, that element will be returned, otherwise an error will be returned containing an iterator that has the same output as the input iterator.
This provides an additional layer of validation over just calling Iterator::next()
.
If your assumption that there should be at most one element yielded is false this provides
the opportunity to detect and handle that, preventing errors at a distance.
Examples
use itertools::Itertools;
assert_eq!((0..10).filter(|&x| x == 2).at_most_one().unwrap(), Some(2));
assert!((0..10).filter(|&x| x > 1 && x < 4).at_most_one().unwrap_err().eq(2..4));
assert!((0..10).filter(|&x| x > 1 && x < 5).at_most_one().unwrap_err().eq(2..5));
assert_eq!((0..10).filter(|&_| false).at_most_one().unwrap(), None);
An iterator adaptor that allows the user to peek at multiple .next()
values without advancing the base iterator.
Examples
use itertools::Itertools;
let mut iter = (0..10).multipeek();
assert_eq!(iter.peek(), Some(&0));
assert_eq!(iter.peek(), Some(&1));
assert_eq!(iter.peek(), Some(&2));
assert_eq!(iter.next(), Some(0));
assert_eq!(iter.peek(), Some(&1));
Collect the items in this iterator and return a HashMap
which
contains each item that appears in the iterator and the number
of times it appears.
Examples
let counts = [1, 1, 1, 3, 3, 5].into_iter().counts();
assert_eq!(counts[&1], 3);
assert_eq!(counts[&3], 2);
assert_eq!(counts[&5], 1);
assert_eq!(counts.get(&0), None);
Collect the items in this iterator and return a HashMap
which
contains each item that appears in the iterator and the number
of times it appears,
determining identity using a keying function.
struct Character {
first_name: &'static str,
last_name: &'static str,
}
let characters =
vec![
Character { first_name: "Amy", last_name: "Pond" },
Character { first_name: "Amy", last_name: "Wong" },
Character { first_name: "Amy", last_name: "Santiago" },
Character { first_name: "James", last_name: "Bond" },
Character { first_name: "James", last_name: "Sullivan" },
Character { first_name: "James", last_name: "Norington" },
Character { first_name: "James", last_name: "Kirk" },
];
let first_name_frequency =
characters
.into_iter()
.counts_by(|c| c.first_name);
assert_eq!(first_name_frequency["Amy"], 3);
assert_eq!(first_name_frequency["James"], 4);
assert_eq!(first_name_frequency.contains_key("Asha"), false);
fn multiunzip<FromI>(self) -> FromI where
Self: Sized + MultiUnzip<FromI>,
fn multiunzip<FromI>(self) -> FromI where
Self: Sized + MultiUnzip<FromI>,
Converts an iterator of tuples into a tuple of containers.
unzip()
consumes an entire iterator of n-ary tuples, producing n
collections, one for each
column.
This function is, in some sense, the opposite of multizip
.
use itertools::Itertools;
let inputs = vec![(1, 2, 3), (4, 5, 6), (7, 8, 9)];
let (a, b, c): (Vec<_>, Vec<_>, Vec<_>) = inputs
.into_iter()
.multiunzip();
assert_eq!(a, vec![1, 4, 7]);
assert_eq!(b, vec![2, 5, 8]);
assert_eq!(c, vec![3, 6, 9]);