T - Component type of the Listpublic interface List<T> extends LinearSeq<T>
List is an eager sequence of elements. Its immutability makes it suitable for concurrent programming.
A List is composed of a head element and a tail List.
There are two implementations of the List interface:
List.Nil, which represents the empty List.List.Cons, which represents a List containing one or more elements.List is a Stack in the sense that it stores elements allowing a last-in-first-out (LIFO) retrieval.
Stack API:
peek()peekOption()pop()popOption()pop2()pop2Option()push(Object)push(Object[])pushAll(Iterable)List:
// factory methods
List.empty() // = List.of() = Nil.instance()
List.of(x) // = new Cons<>(x, Nil.instance())
List.of(Object...) // e.g. List.of(1, 2, 3)
List.ofAll(Iterable) // e.g. List.ofAll(Stream.of(1, 2, 3)) = 1, 2, 3
List.ofAll(<primitive array>) // e.g. List.of(new int[] {1, 2, 3}) = 1, 2, 3
// int sequences
List.range(0, 3) // = 0, 1, 2
List.rangeClosed(0, 3) // = 0, 1, 2, 3
Note: A List is primarily a Seq and extends Stack for technical reasons (so Stack does not need to wrap List).
If operating on a List, please prefer
prepend(Object) over push(Object)prependAll(Iterable) over pushAll(Iterable)tail() over pop()tailOption() over popOption()
List<Integer> s1 = List.of(1);
List<Integer> s2 = List.of(1, 2, 3);
// = List.of(new Integer[] {1, 2, 3});
List<int[]> s3 = List.ofAll(1, 2, 3);
List<List<Integer>> s4 = List.ofAll(List.of(1, 2, 3));
List<Integer> s5 = List.ofAll(1, 2, 3);
List<Integer> s6 = List.ofAll(List.of(1, 2, 3));
// cuckoo's egg
List<Integer[]> s7 = List.<Integer[]> of(new Integer[] {1, 2, 3});
Example: Converting a String to digits
// = List(1, 2, 3)
List.of("123".toCharArray()).map(c -> Character.digit(c, 10))
See Okasaki, Chris: Purely Functional Data Structures (p. 7 ff.). Cambridge, 2003.| Modifier and Type | Interface and Description |
|---|---|
static class |
List.Cons<T>
Non-empty
List, consisting of a head and a tail. |
static class |
List.Nil<T>
Representation of the singleton empty
List. |
| Modifier and Type | Field and Description |
|---|---|
static long |
serialVersionUID |
| Modifier and Type | Method and Description |
|---|---|
default List<T> |
append(T element)
Appends an element to this.
|
default List<T> |
appendAll(Iterable<? extends T> elements)
Appends all given elements to this.
|
default List<T> |
asJava()
Creates an immutable
List view on top of this Seq,
i.e. |
default List<T> |
asJava(Consumer<? super List<T>> action)
|
default List<T> |
asJavaMutable()
Creates a mutable
List view on top of this Seq,
i.e. |
default List<T> |
asJavaMutable(Consumer<? super List<T>> action)
|
default <R> List<R> |
collect(PartialFunction<? super T,? extends R> partialFunction)
Collects all elements that are in the domain of the given
partialFunction by mapping the elements to type R. |
static <T> Collector<T,ArrayList<T>,List<T>> |
collector()
Returns a
Collector which may be used in conjunction with
Stream.collect(java.util.stream.Collector) to obtain a List. |
default List<List<T>> |
combinations()
Returns the union of all combinations from k = 0 to length().
|
default List<List<T>> |
combinations(int k)
Returns the k-combination of this traversable, i.e.
|
default Iterator<List<T>> |
crossProduct(int power)
Calculates the n-ary cartesian power (or cross product or simply product) of this.
|
default List<T> |
distinct()
Returns a new version of this which contains no duplicates.
|
default List<T> |
distinctBy(Comparator<? super T> comparator)
Returns a new version of this which contains no duplicates.
|
default <U> List<T> |
distinctBy(Function<? super T,? extends U> keyExtractor)
Returns a new version of this which contains no duplicates.
|
default List<T> |
drop(int n)
Drops the first n elements of this or all elements, if this length < n.
|
default List<T> |
dropRight(int n)
Drops the last n elements of this or all elements, if this length < n.
|
default List<T> |
dropRightUntil(Predicate<? super T> predicate)
Drops elements until the predicate holds for the current element, starting from the end.
|
default List<T> |
dropRightWhile(Predicate<? super T> predicate)
Drops elements while the predicate holds for the current element, starting from the end.
|
default List<T> |
dropUntil(Predicate<? super T> predicate)
Drops elements until the predicate holds for the current element.
|
default List<T> |
dropWhile(Predicate<? super T> predicate)
Drops elements while the predicate holds for the current element.
|
static <T> List<T> |
empty()
Returns the single instance of Nil.
|
static <T> List<T> |
fill(int n,
Supplier<? extends T> s)
Returns a List containing
n values supplied by a given Supplier s. |
static <T> List<T> |
fill(int n,
T element)
Returns a List containing
n times the given element |
default List<T> |
filter(Predicate<? super T> predicate)
Returns a new traversable consisting of all elements which satisfy the given predicate.
|
default <U> List<U> |
flatMap(Function<? super T,? extends Iterable<? extends U>> mapper)
FlatMaps this Traversable.
|
default T |
get(int index)
Returns the element at the specified index.
|
default <C> Map<C,List<T>> |
groupBy(Function<? super T,? extends C> classifier)
Groups this elements by classifying the elements.
|
default Iterator<List<T>> |
grouped(int size)
Groups this
Traversable into fixed size blocks. |
default boolean |
hasDefiniteSize()
Checks if this Traversable is known to have a finite size.
|
default int |
indexOf(T element,
int from)
Returns the index of the first occurrence of the given element after or at some start index
or -1 if this does not contain the given element.
|
default List<T> |
init()
Dual of Traversable.tail(), returning all elements except the last.
|
default Option<List<T>> |
initOption()
Dual of Traversable.tailOption(), returning all elements except the last as
Option. |
default List<T> |
insert(int index,
T element)
Inserts the given element at the specified index.
|
default List<T> |
insertAll(int index,
Iterable<? extends T> elements)
Inserts the given elements at the specified index.
|
default List<T> |
intersperse(T element)
Inserts an element between all elements of this Traversable.
|
default boolean |
isAsync()
A
List is computed synchronously. |
boolean |
isEmpty()
Checks if this Traversable is empty.
|
default boolean |
isLazy()
A
List is computed eagerly. |
default boolean |
isTraversableAgain()
Checks if this Traversable can be repeatedly traversed.
|
default T |
last()
Dual of Traversable.head(), returning the last element.
|
default int |
lastIndexOf(T element,
int end)
Returns the index of the last occurrence of the given element before or at a given end index
or -1 if this does not contain the given element.
|
default List<T> |
leftPadTo(int length,
T element)
A copy of this sequence with an element prepended until a given target length is reached.
|
int |
length()
Computes the number of elements of this Traversable.
|
default <U> List<U> |
map(Function<? super T,? extends U> mapper)
Maps the elements of this
Traversable to elements of a new type preserving their order, if any. |
static <T> List<T> |
narrow(List<? extends T> list)
Narrows a widened
List<? extends T> to List<T>
by performing a type-safe cast. |
static <T> List<T> |
of(T... elements)
Creates a List of the given elements.
|
static <T> List<T> |
of(T element)
Returns a singleton
List, i.e. |
static List<Boolean> |
ofAll(boolean... elements)
Creates a List from boolean values.
|
static List<Byte> |
ofAll(byte... elements)
Creates a List from byte values.
|
static List<Character> |
ofAll(char... elements)
Creates a List from char values.
|
static List<Double> |
ofAll(double... elements)
Creates a List from double values.
|
static List<Float> |
ofAll(float... elements)
Creates a List from float values.
|
static List<Integer> |
ofAll(int... elements)
Creates a List from int values.
|
static <T> List<T> |
ofAll(Iterable<? extends T> elements)
Creates a List of the given elements.
|
static List<Long> |
ofAll(long... elements)
Creates a List from long values.
|
static List<Short> |
ofAll(short... elements)
Creates a List from short values.
|
static <T> List<T> |
ofAll(Stream<? extends T> javaStream)
Creates a List that contains the elements of the given
Stream. |
default List<T> |
orElse(Iterable<? extends T> other)
Returns this
Traversable if it is nonempty, otherwise return the alternative. |
default List<T> |
orElse(Supplier<? extends Iterable<? extends T>> supplier)
Returns this
Traversable if it is nonempty, otherwise return the result of evaluating supplier. |
default List<T> |
padTo(int length,
T element)
A copy of this sequence with an element appended until a given target length is reached.
|
default Tuple2<List<T>,List<T>> |
partition(Predicate<? super T> predicate)
Creates a partition of this
Traversable by splitting this elements in two in distinct traversables
according to a predicate. |
default List<T> |
patch(int from,
Iterable<? extends T> that,
int replaced)
Produces a new list where a slice of elements in this list is replaced by another sequence.
|
default T |
peek()
Returns the head element without modifying the List.
|
default List<T> |
peek(Consumer<? super T> action)
Performs an action on the head element of this
List. |
default Option<T> |
peekOption()
Returns the head element without modifying the List.
|
default List<List<T>> |
permutations()
Computes all unique permutations.
|
default List<T> |
pop()
Removes the head element from this List.
|
default Tuple2<T,List<T>> |
pop2()
Removes the head element from this List.
|
default Option<Tuple2<T,List<T>>> |
pop2Option()
Removes the head element from this List.
|
default Option<List<T>> |
popOption()
Removes the head element from this List.
|
default List<T> |
prepend(T element)
Prepends an element to this.
|
default List<T> |
prependAll(Iterable<? extends T> elements)
Prepends all given elements to this.
|
default List<T> |
push(T... elements)
Pushes the given elements on top of this List.
|
default List<T> |
push(T element)
Pushes a new element on top of this List.
|
default List<T> |
pushAll(Iterable<T> elements)
Pushes the given elements on top of this List.
|
static List<Character> |
range(char from,
char toExclusive) |
static List<Integer> |
range(int from,
int toExclusive)
Creates a List of int numbers starting from
from, extending to toExclusive - 1. |
static List<Long> |
range(long from,
long toExclusive)
Creates a List of long numbers starting from
from, extending to toExclusive - 1. |
static List<Character> |
rangeBy(char from,
char toExclusive,
int step) |
static List<Double> |
rangeBy(double from,
double toExclusive,
double step) |
static List<Integer> |
rangeBy(int from,
int toExclusive,
int step)
Creates a List of int numbers starting from
from, extending to toExclusive - 1,
with step. |
static List<Long> |
rangeBy(long from,
long toExclusive,
long step)
Creates a List of long numbers starting from
from, extending to toExclusive - 1,
with step. |
static List<Character> |
rangeClosed(char from,
char toInclusive) |
static List<Integer> |
rangeClosed(int from,
int toInclusive)
Creates a List of int numbers starting from
from, extending to toInclusive. |
static List<Long> |
rangeClosed(long from,
long toInclusive)
Creates a List of long numbers starting from
from, extending to toInclusive. |
static List<Character> |
rangeClosedBy(char from,
char toInclusive,
int step) |
static List<Double> |
rangeClosedBy(double from,
double toInclusive,
double step) |
static List<Integer> |
rangeClosedBy(int from,
int toInclusive,
int step)
Creates a List of int numbers starting from
from, extending to toInclusive,
with step. |
static List<Long> |
rangeClosedBy(long from,
long toInclusive,
long step)
Creates a List of long numbers starting from
from, extending to toInclusive,
with step. |
default List<T> |
reject(Predicate<? super T> predicate)
Returns a new traversable consisting of all elements which do not satisfy the given predicate.
|
default List<T> |
remove(T element)
Removes the first occurrence of the given element.
|
default List<T> |
removeAll(Iterable<? extends T> elements)
Removes all occurrences of the given elements.
|
default List<T> |
removeAll(Predicate<? super T> predicate)
Deprecated.
|
default List<T> |
removeAll(T element)
Removes all occurrences of the given element.
|
default List<T> |
removeAt(int index)
Removes the element at the specified position in this sequence.
|
default List<T> |
removeFirst(Predicate<T> predicate)
Removes the first occurrence that satisfy predicate
|
default List<T> |
removeLast(Predicate<T> predicate)
Removes the last occurrence that satisfy predicate
|
default List<T> |
replace(T currentElement,
T newElement)
Replaces the first occurrence (if exists) of the given currentElement with newElement.
|
default List<T> |
replaceAll(T currentElement,
T newElement)
Replaces all occurrences of the given currentElement with newElement.
|
default List<T> |
retainAll(Iterable<? extends T> elements)
Keeps all occurrences of the given elements from this.
|
default List<T> |
reverse()
Reverses the order of elements.
|
default List<T> |
rotateLeft(int n)
Circular rotates the elements by the specified distance to the left direction.
|
default List<T> |
rotateRight(int n)
Circular rotates the elements by the specified distance to the right direction.
|
default List<T> |
scan(T zero,
BiFunction<? super T,? super T,? extends T> operation)
Computes a prefix scan of the elements of the collection.
|
default <U> List<U> |
scanLeft(U zero,
BiFunction<? super U,? super T,? extends U> operation)
Produces a collection containing cumulative results of applying the
operator going left to right.
|
default <U> List<U> |
scanRight(U zero,
BiFunction<? super T,? super U,? extends U> operation)
Produces a collection containing cumulative results of applying the
operator going right to left.
|
default List<T> |
shuffle()
Randomize the order of the elements in the current sequence.
|
default List<T> |
slice(int beginIndex,
int endIndex)
Returns a Seq that is a slice of this.
|
default Iterator<List<T>> |
slideBy(Function<? super T,?> classifier)
Slides a non-overlapping window of a variable size over this
Traversable. |
default Iterator<List<T>> |
sliding(int size)
Slides a window of a specific
size and step size 1 over this Traversable by calling
Traversable.sliding(int, int). |
default Iterator<List<T>> |
sliding(int size,
int step)
Slides a window of a specific
size and step size over this Traversable. |
default <U> List<T> |
sortBy(Comparator<? super U> comparator,
Function<? super T,? extends U> mapper)
Sorts this elements by comparing the elements in a different domain, using the given
mapper. |
default <U extends Comparable<? super U>> |
sortBy(Function<? super T,? extends U> mapper)
Sorts this elements by comparing the elements in a different domain, using the given
mapper. |
default List<T> |
sorted()
Sorts this elements according to their natural order.
|
default List<T> |
sorted(Comparator<? super T> comparator)
Sorts this elements according to the provided
Comparator. |
default Tuple2<List<T>,List<T>> |
span(Predicate<? super T> predicate)
Returns a tuple where the first element is the longest prefix of elements that satisfy the given
predicate and the second element is the remainder. |
default Tuple2<List<T>,List<T>> |
splitAt(int n)
Splits a Seq at the specified index.
|
default Tuple2<List<T>,List<T>> |
splitAt(Predicate<? super T> predicate)
Splits a sequence at the first element which satisfies the
Predicate, e.g. |
default Tuple2<List<T>,List<T>> |
splitAtInclusive(Predicate<? super T> predicate)
Splits a sequence at the first element which satisfies the
Predicate, e.g. |
default String |
stringPrefix()
Returns the name of this Value type, which is used by toString().
|
default List<T> |
subSequence(int beginIndex)
Returns a Seq that is a subsequence of this.
|
default List<T> |
subSequence(int beginIndex,
int endIndex)
Returns a Seq that is a subsequence of this.
|
static <T> List<T> |
tabulate(int n,
Function<? super Integer,? extends T> f)
Returns a List containing
n values of a given Function f
over a range of integer values from 0 to n - 1. |
List<T> |
tail()
Drops the first element of a non-empty Traversable.
|
default Option<List<T>> |
tailOption()
Drops the first element of a non-empty Traversable and returns an
Option. |
default List<T> |
take(int n)
Takes the first n elements of this or all elements, if this length < n.
|
default List<T> |
takeRight(int n)
Takes the last n elements of this or all elements, if this length < n.
|
default List<T> |
takeRightUntil(Predicate<? super T> predicate)
Takes elements until the predicate holds for the current element, starting from the end.
|
default List<T> |
takeRightWhile(Predicate<? super T> predicate)
Takes elements while the predicate holds for the current element, starting from the end.
|
default List<T> |
takeUntil(Predicate<? super T> predicate)
Takes elements until the predicate holds for the current element.
|
default List<T> |
takeWhile(Predicate<? super T> predicate)
Takes elements while the predicate holds for the current element.
|
default <U> U |
transform(Function<? super List<T>,? extends U> f)
Transforms this
List. |
static <T> List<List<T>> |
transpose(List<List<T>> matrix)
Transposes the rows and columns of a
List matrix. |
static <T> List<T> |
unfold(T seed,
Function<? super T,Option<Tuple2<? extends T,? extends T>>> f)
Creates a list from a seed value and a function.
|
static <T,U> List<U> |
unfoldLeft(T seed,
Function<? super T,Option<Tuple2<? extends T,? extends U>>> f)
Creates a list from a seed value and a function.
|
static <T,U> List<U> |
unfoldRight(T seed,
Function<? super T,Option<Tuple2<? extends U,? extends T>>> f)
Creates a list from a seed value and a function.
|
default <T1,T2> Tuple2<List<T1>,List<T2>> |
unzip(Function<? super T,Tuple2<? extends T1,? extends T2>> unzipper)
Unzips this elements by mapping this elements to pairs which are subsequently split into two distinct
sets.
|
default <T1,T2,T3> Tuple3<List<T1>,List<T2>,List<T3>> |
unzip3(Function<? super T,Tuple3<? extends T1,? extends T2,? extends T3>> unzipper)
Unzips this elements by mapping this elements to triples which are subsequently split into three distinct
sets.
|
default List<T> |
update(int index,
Function<? super T,? extends T> updater)
Updates the given element at the specified index using the specified function.
|
default List<T> |
update(int index,
T element)
Updates the given element at the specified index.
|
default <U> List<Tuple2<T,U>> |
zip(Iterable<? extends U> that)
Returns a traversable formed from this traversable and another Iterable collection by combining
corresponding elements in pairs.
|
default <U> List<Tuple2<T,U>> |
zipAll(Iterable<? extends U> that,
T thisElem,
U thatElem)
Returns a traversable formed from this traversable and another Iterable by combining corresponding elements in
pairs.
|
default <U,R> List<R> |
zipWith(Iterable<? extends U> that,
BiFunction<? super T,? super U,? extends R> mapper)
Returns a traversable formed from this traversable and another Iterable collection by mapping elements.
|
default List<Tuple2<T,Integer>> |
zipWithIndex()
Zips this traversable with its indices.
|
default <U> List<U> |
zipWithIndex(BiFunction<? super T,? super Integer,? extends U> mapper)
Returns a traversable formed from this traversable and another Iterable collection by mapping elements.
|
asPartialFunction, indexOfSlice, indexWhere, isDefinedAt, lastIndexOfSlice, lastIndexWhere, narrow, reverseIterator, search, search, segmentLengthapply, containsSlice, crossProduct, crossProduct, endsWith, foldRight, indexOf, indexOfOption, indexOfOption, indexOfSlice, indexOfSliceOption, indexOfSliceOption, indexWhere, indexWhereOption, indexWhereOption, isSequential, iterator, lastIndexOf, lastIndexOfOption, lastIndexOfOption, lastIndexOfSlice, lastIndexOfSliceOption, lastIndexOfSliceOption, lastIndexWhere, lastIndexWhereOption, lastIndexWhereOption, lift, narrow, prefixLength, startsWith, startsWith, withDefault, withDefaultValuearrangeBy, average, containsAll, count, equals, existsUnique, find, findLast, foldLeft, forEachWithIndex, get, hashCode, head, headOption, isDistinct, isOrdered, isSingleValued, iterator, lastOption, max, maxBy, maxBy, min, minBy, minBy, mkCharSeq, mkCharSeq, mkCharSeq, mkString, mkString, mkString, narrow, nonEmpty, product, reduceLeft, reduceLeftOption, reduceRight, reduceRightOption, single, singleOption, size, spliterator, sumfold, reduce, reduceOptioncollect, collect, contains, corresponds, eq, exists, forAll, forEach, getOrElse, getOrElse, getOrElseThrow, getOrElseTry, getOrNull, narrow, out, out, stderr, stdout, toArray, toCharSeq, toCompletableFuture, toEither, toEither, toInvalid, toInvalid, toJavaArray, toJavaArray, toJavaArray, toJavaCollection, toJavaList, toJavaList, toJavaMap, toJavaMap, toJavaMap, toJavaOptional, toJavaParallelStream, toJavaSet, toJavaSet, toJavaStream, toLeft, toLeft, toLinkedMap, toLinkedMap, toLinkedSet, toList, toMap, toMap, toOption, toPriorityQueue, toPriorityQueue, toQueue, toRight, toRight, toSet, toSortedMap, toSortedMap, toSortedMap, toSortedMap, toSortedSet, toSortedSet, toStream, toString, toTree, toTree, toTry, toTry, toValid, toValid, toValidation, toValidation, toVectorgetIfDefined, unliftstatic final long serialVersionUID
static <T> Collector<T,ArrayList<T>,List<T>> collector()
Collector which may be used in conjunction with
Stream.collect(java.util.stream.Collector) to obtain a List.T - Component type of the List.static <T> List<T> empty()
Nil.instance() .
Note: this method intentionally returns type List and not Nil. This comes handy when folding.
If you explicitly need type Nil use List.Nil.instance().
T - Component type of Nil, determined by type inference in the particular context.default boolean isAsync()
List is computed synchronously.boolean isEmpty()
Traversabledefault boolean isLazy()
List is computed eagerly.static <T> List<T> narrow(List<? extends T> list)
List<? extends T> to List<T>
by performing a type-safe cast. This is eligible because immutable/read-only
collections are covariant.T - Component type of the List.list - A List.list instance as narrowed type List<T>.static <T> List<T> of(T element)
List, i.e. a List of one element.@SafeVarargs static <T> List<T> of(T... elements)
List.of(1, 2, 3, 4)
= Nil.instance().prepend(4).prepend(3).prepend(2).prepend(1)
= new Cons(1, new Cons(2, new Cons(3, new Cons(4, Nil.instance()))))
T - Component type of the List.elements - Zero or more elements.NullPointerException - if elements is nullstatic <T> List<T> ofAll(Iterable<? extends T> elements)
The resulting list has the same iteration order as the given iterable of elements if the iteration order of the elements is stable.
T - Component type of the List.elements - An Iterable of elements.NullPointerException - if elements is nullstatic <T> List<T> ofAll(Stream<? extends T> javaStream)
Stream.T - Component type of the Stream.javaStream - A Streamstatic List<Boolean> ofAll(boolean... elements)
elements - boolean valuesNullPointerException - if elements is nullstatic List<Byte> ofAll(byte... elements)
elements - byte valuesNullPointerException - if elements is nullstatic List<Character> ofAll(char... elements)
elements - char valuesNullPointerException - if elements is nullstatic List<Double> ofAll(double... elements)
elements - double valuesNullPointerException - if elements is nullstatic List<Float> ofAll(float... elements)
elements - a float valuesNullPointerException - if elements is nullstatic List<Integer> ofAll(int... elements)
elements - int valuesNullPointerException - if elements is nullstatic List<Long> ofAll(long... elements)
elements - long valuesNullPointerException - if elements is nullstatic List<Short> ofAll(short... elements)
elements - short valuesNullPointerException - if elements is nullstatic <T> List<T> tabulate(int n, Function<? super Integer,? extends T> f)
n values of a given Function f
over a range of integer values from 0 to n - 1.T - Component type of the Listn - The number of elements in the Listf - The Function computing element valuesf(0),f(1), ..., f(n - 1)NullPointerException - if f is nullstatic <T> List<T> fill(int n, Supplier<? extends T> s)
n values supplied by a given Supplier s.T - Component type of the Listn - The number of elements in the Lists - The Supplier computing element valuesn, where each element contains the result supplied by s.NullPointerException - if s is nullstatic <T> List<T> fill(int n, T element)
n times the given elementT - Component type of the Listn - The number of elements in the Listelement - The elementn, where each element is the given element.static List<Integer> range(int from, int toExclusive)
from, extending to toExclusive - 1.
Examples:
List.range(0, 0) // = List()
List.range(2, 0) // = List()
List.range(-2, 2) // = List(-2, -1, 0, 1)
from - the first numbertoExclusive - the last number + 1from >= toExclusivestatic List<Integer> rangeBy(int from, int toExclusive, int step)
from, extending to toExclusive - 1,
with step.
Examples:
List.rangeBy(1, 3, 1) // = List(1, 2)
List.rangeBy(1, 4, 2) // = List(1, 3)
List.rangeBy(4, 1, -2) // = List(4, 2)
List.rangeBy(4, 1, 2) // = List()
from - the first numbertoExclusive - the last number + 1step - the stepfrom >= toInclusive and step > 0 orfrom <= toInclusive and step < 0IllegalArgumentException - if step is zerostatic List<Long> range(long from, long toExclusive)
from, extending to toExclusive - 1.
Examples:
List.range(0L, 0L) // = List()
List.range(2L, 0L) // = List()
List.range(-2L, 2L) // = List(-2L, -1L, 0L, 1L)
from - the first numbertoExclusive - the last number + 1from >= toExclusivestatic List<Long> rangeBy(long from, long toExclusive, long step)
from, extending to toExclusive - 1,
with step.
Examples:
List.rangeBy(1L, 3L, 1L) // = List(1L, 2L)
List.rangeBy(1L, 4L, 2L) // = List(1L, 3L)
List.rangeBy(4L, 1L, -2L) // = List(4L, 2L)
List.rangeBy(4L, 1L, 2L) // = List()
from - the first numbertoExclusive - the last number + 1step - the stepfrom >= toInclusive and step > 0 orfrom <= toInclusive and step < 0IllegalArgumentException - if step is zero@GwtIncompatible static List<Double> rangeClosedBy(double from, double toInclusive, double step)
static List<Integer> rangeClosed(int from, int toInclusive)
from, extending to toInclusive.
Examples:
List.rangeClosed(0, 0) // = List(0)
List.rangeClosed(2, 0) // = List()
List.rangeClosed(-2, 2) // = List(-2, -1, 0, 1, 2)
from - the first numbertoInclusive - the last numberfrom > toInclusivestatic List<Integer> rangeClosedBy(int from, int toInclusive, int step)
from, extending to toInclusive,
with step.
Examples:
List.rangeClosedBy(1, 3, 1) // = List(1, 2, 3)
List.rangeClosedBy(1, 4, 2) // = List(1, 3)
List.rangeClosedBy(4, 1, -2) // = List(4, 2)
List.rangeClosedBy(4, 1, 2) // = List()
from - the first numbertoInclusive - the last numberstep - the stepfrom > toInclusive and step > 0 orfrom < toInclusive and step < 0IllegalArgumentException - if step is zerostatic List<Long> rangeClosed(long from, long toInclusive)
from, extending to toInclusive.
Examples:
List.rangeClosed(0L, 0L) // = List(0L)
List.rangeClosed(2L, 0L) // = List()
List.rangeClosed(-2L, 2L) // = List(-2L, -1L, 0L, 1L, 2L)
from - the first numbertoInclusive - the last numberfrom > toInclusivestatic List<Long> rangeClosedBy(long from, long toInclusive, long step)
from, extending to toInclusive,
with step.
Examples:
List.rangeClosedBy(1L, 3L, 1L) // = List(1L, 2L, 3L)
List.rangeClosedBy(1L, 4L, 2L) // = List(1L, 3L)
List.rangeClosedBy(4L, 1L, -2L) // = List(4L, 2L)
List.rangeClosedBy(4L, 1L, 2L) // = List()
from - the first numbertoInclusive - the last numberstep - the stepfrom > toInclusive and step > 0 orfrom < toInclusive and step < 0IllegalArgumentException - if step is zerostatic <T> List<List<T>> transpose(List<List<T>> matrix)
List matrix.T - matrix element typematrix - to be transposed.List matrix.IllegalArgumentException - if the row lengths of matrix differ.
ex: List.transpose(List(List(1,2,3), List(4,5,6))) → List(List(1,4), List(2,5), List(3,6))
static <T,U> List<U> unfoldRight(T seed, Function<? super T,Option<Tuple2<? extends U,? extends T>>> f)
None when it's
done generating the list, otherwise Some Tuple
of the element for the next call and the value to add to the
resulting list.
Example:
List.unfoldRight(10, x -> x == 0
? Option.none()
: Option.of(new Tuple2<>(x, x-1)));
// List(10, 9, 8, 7, 6, 5, 4, 3, 2, 1))
T - type of seedsU - type of unfolded valuesseed - the start value for the iterationf - the function to get the next step of the iterationNullPointerException - if f is nullstatic <T,U> List<U> unfoldLeft(T seed, Function<? super T,Option<Tuple2<? extends T,? extends U>>> f)
None when it's
done generating the list, otherwise Some Tuple
of the value to add to the resulting list and
the element for the next call.
Example:
List.unfoldLeft(10, x -> x == 0
? Option.none()
: Option.of(new Tuple2<>(x-1, x)));
// List(1, 2, 3, 4, 5, 6, 7, 8, 9, 10))
T - type of seedsU - type of unfolded valuesseed - the start value for the iterationf - the function to get the next step of the iterationNullPointerException - if f is nullstatic <T> List<T> unfold(T seed, Function<? super T,Option<Tuple2<? extends T,? extends T>>> f)
None when it's
done generating the list, otherwise Some Tuple
of the value to add to the resulting list and
the element for the next call.
Example:
List.unfold(10, x -> x == 0
? Option.none()
: Option.of(new Tuple2<>(x-1, x)));
// List(1, 2, 3, 4, 5, 6, 7, 8, 9, 10))
T - type of seeds and unfolded valuesseed - the start value for the iterationf - the function to get the next step of the iterationNullPointerException - if f is nulldefault List<T> append(T element)
Seqdefault List<T> appendAll(Iterable<? extends T> elements)
Seq@GwtIncompatible default List<T> asJava()
SeqList view on top of this Seq,
i.e. calling mutators will result in UnsupportedOperationException at runtime.
The difference to conversion methods toJava*() is that
java.util.List view throws UnsupportedOperationException before
checking method arguments. Java does handle this case inconsistently.asJava in interface Seq<T>Collection view on this Traversable.@GwtIncompatible default List<T> asJava(Consumer<? super List<T>> action)
Seq@GwtIncompatible default List<T> asJavaMutable()
SeqList view on top of this Seq,
i.e. all mutator methods of the List are implemented.asJavaMutable in interface Seq<T>Collection view on this Traversable.Seq.asJava()@GwtIncompatible default List<T> asJavaMutable(Consumer<? super List<T>> action)
SeqasJavaMutable in interface LinearSeq<T>asJavaMutable in interface Seq<T>action - A side-effecting unit of work that operates on a mutable java.util.List view.java.util.List view or a new instance of this type, if write operations are performed on the java.util.List view.Seq.asJavaMutable()default <R> List<R> collect(PartialFunction<? super T,? extends R> partialFunction)
TraversablepartialFunction by mapping the elements to type R.
More specifically, for each of this elements in iteration order first it is checked
partialFunction.isDefinedAt(element)
R newElement = partialFunction.apply(element)
Traversable is ordered (i.e. extends Ordered,
the caller of collect has to ensure that the elements are comparable (i.e. extend Comparable).collect in interface LinearSeq<T>collect in interface Seq<T>collect in interface Traversable<T>R - The new element typepartialFunction - A function that is not necessarily defined of all elements of this traversable.Traversable instance containing elements of type Rdefault List<List<T>> combinations()
SeqExamples:
[].combinations() = [[]]
[1,2,3].combinations() = [
[], // k = 0
[1], [2], [3], // k = 1
[1,2], [1,3], [2,3], // k = 2
[1,2,3] // k = 3
]
combinations in interface LinearSeq<T>combinations in interface Seq<T>default List<List<T>> combinations(int k)
Seqcombinations in interface LinearSeq<T>combinations in interface Seq<T>k - Size of subsetsdefault Iterator<List<T>> crossProduct(int power)
SeqExample:
// = ((A,A), (A,B), (A,C), ..., (B,A), (B,B), ..., (Z,Y), (Z,Z))
CharSeq.rangeClosed('A', 'Z').crossProduct(2);
Cartesian power of negative value will return empty iterator.
Example:
// = ()
CharSeq.rangeClosed('A', 'Z').crossProduct(-1);
crossProduct in interface LinearSeq<T>crossProduct in interface Seq<T>power - the number of cartesian multiplicationsdefault List<T> distinct()
Traversableequals.default List<T> distinctBy(Comparator<? super T> comparator)
Traversablecomparator.distinctBy in interface LinearSeq<T>distinctBy in interface Seq<T>distinctBy in interface Traversable<T>comparator - A comparatorTraversable containing this elements without duplicatesdefault <U> List<T> distinctBy(Function<? super T,? extends U> keyExtractor)
Traversableequals.
The elements of the result are determined in the order of their occurrence - first match wins.
distinctBy in interface LinearSeq<T>distinctBy in interface Seq<T>distinctBy in interface Traversable<T>U - key typekeyExtractor - A key extractorTraversable containing this elements without duplicatesdefault List<T> drop(int n)
Traversabledrop in interface LinearSeq<T>drop in interface Seq<T>drop in interface Traversable<T>n - The number of elements to drop.default List<T> dropUntil(Predicate<? super T> predicate)
TraversabledropUntil in interface LinearSeq<T>dropUntil in interface Seq<T>dropUntil in interface Traversable<T>predicate - A condition tested subsequently for this elements.default List<T> dropWhile(Predicate<? super T> predicate)
Traversable
Note: This is essentially the same as dropUntil(predicate.negate()).
It is intended to be used with method references, which cannot be negated directly.
dropWhile in interface LinearSeq<T>dropWhile in interface Seq<T>dropWhile in interface Traversable<T>predicate - A condition tested subsequently for this elements.default List<T> dropRight(int n)
TraversabledropRight in interface LinearSeq<T>dropRight in interface Seq<T>dropRight in interface Traversable<T>n - The number of elements to drop.default List<T> dropRightUntil(Predicate<? super T> predicate)
SeqdropRightUntil in interface LinearSeq<T>dropRightUntil in interface Seq<T>predicate - A condition tested subsequently for this elements, starting from the end.default List<T> dropRightWhile(Predicate<? super T> predicate)
Seq
Note: This is essentially the same as dropRightUntil(predicate.negate()).
It is intended to be used with method references, which cannot be negated directly.
dropRightWhile in interface LinearSeq<T>dropRightWhile in interface Seq<T>predicate - A condition tested subsequently for this elements, starting from the end.default List<T> filter(Predicate<? super T> predicate)
Traversabledefault List<T> reject(Predicate<? super T> predicate)
TraversableThe default implementation is equivalent to
filter(predicate.negate()default <U> List<U> flatMap(Function<? super T,? extends Iterable<? extends U>> mapper)
Traversabledefault T get(int index)
Seqdefault <C> Map<C,List<T>> groupBy(Function<? super T,? extends C> classifier)
TraversablegroupBy in interface LinearSeq<T>groupBy in interface Seq<T>groupBy in interface Traversable<T>C - classified class typeclassifier - A function which classifies elements into classesTraversable.arrangeBy(Function)default Iterator<List<T>> grouped(int size)
TraversableTraversable into fixed size blocks.
Let length be the length of this Iterable. Then grouped is defined as follows:
this.isEmpty(), the resulting Iterator is empty.size <= length, the resulting Iterator will contain length / size blocks of size
size and maybe a non-empty block of size length % size, if there are remaining elements.size > length, the resulting Iterator will contain one block of size length.
[].grouped(1) = []
[].grouped(0) throws
[].grouped(-1) throws
[1,2,3,4].grouped(2) = [[1,2],[3,4]]
[1,2,3,4,5].grouped(2) = [[1,2],[3,4],[5]]
[1,2,3,4].grouped(5) = [[1,2,3,4]]
Please note that grouped(int) is a special case of Traversable.sliding(int, int), i.e.
grouped(size) is the same as sliding(size, size).default boolean hasDefiniteSize()
TraversableThis method should be implemented by classes only, i.e. not by interfaces.
hasDefiniteSize in interface Traversable<T>default int indexOf(T element, int from)
Seqdefault List<T> init()
Traversabledefault Option<List<T>> initOption()
TraversableOption.initOption in interface LinearSeq<T>initOption in interface Seq<T>initOption in interface Traversable<T>Some(traversable) or None if this is empty.int length()
Traversable
Same as Traversable.size().
length in interface Traversable<T>default List<T> insert(int index, T element)
Seqdefault List<T> insertAll(int index, Iterable<? extends T> elements)
Seqdefault List<T> intersperse(T element)
Seqintersperse in interface LinearSeq<T>intersperse in interface Seq<T>element - An element.default boolean isTraversableAgain()
TraversableThis method should be implemented by classes only, i.e. not by interfaces.
isTraversableAgain in interface Traversable<T>default T last()
Traversablelast in interface Traversable<T>default int lastIndexOf(T element, int end)
SeqlastIndexOf in interface Seq<T>element - an elementend - the end indexdefault <U> List<U> map(Function<? super T,? extends U> mapper)
TraversableTraversable to elements of a new type preserving their order, if any.default List<T> orElse(Iterable<? extends T> other)
TraversableTraversable if it is nonempty, otherwise return the alternative.default List<T> orElse(Supplier<? extends Iterable<? extends T>> supplier)
TraversableTraversable if it is nonempty, otherwise return the result of evaluating supplier.default List<T> padTo(int length, T element)
SeqNote: lazily-evaluated Seq implementations need to process all elements in order to gather the overall length.
padTo in interface LinearSeq<T>padTo in interface Seq<T>length - the target lengthelement - the padding elementelement so that the resulting sequence has a length of at least length.default List<T> leftPadTo(int length, T element)
SeqNote: lazily-evaluated Seq implementations need to process all elements in order to gather the overall length.
leftPadTo in interface Seq<T>length - the target lengthelement - the padding elementelement so that the resulting sequence has a length of at least length.default List<T> patch(int from, Iterable<? extends T> that, int replaced)
Seqdefault Tuple2<List<T>,List<T>> partition(Predicate<? super T> predicate)
TraversableTraversable by splitting this elements in two in distinct traversables
according to a predicate.partition in interface LinearSeq<T>partition in interface Seq<T>partition in interface Traversable<T>predicate - A predicate which classifies an element if it is in the first or the second traversable.Traversable contains all elements that satisfy the given predicate, the second Traversable contains all elements that don't. The original order of elements is preserved.default T peek()
NoSuchElementException - if this List is emptydefault Option<T> peekOption()
None if this List is empty, otherwise a Some containing the head elementdefault List<T> peek(Consumer<? super T> action)
List.default List<List<T>> permutations()
SeqExample:
[].permutations() = []
[1,2,3].permutations() = [
[1,2,3],
[1,3,2],
[2,1,3],
[2,3,1],
[3,1,2],
[3,2,1]
]
permutations in interface LinearSeq<T>permutations in interface Seq<T>default List<T> pop()
NoSuchElementException - if this List is emptydefault Option<List<T>> popOption()
None if this List is empty, otherwise a Some containing the elements of this List without the head elementdefault Tuple2<T,List<T>> pop2()
NoSuchElementException - if this List is emptydefault Option<Tuple2<T,List<T>>> pop2Option()
None if this List is empty, otherwise Some Tuple containing the head element and the remaining elements of this Listdefault List<T> prepend(T element)
Seqdefault List<T> prependAll(Iterable<? extends T> elements)
SeqprependAll in interface LinearSeq<T>prependAll in interface Seq<T>elements - An Iterable of elementsdefault List<T> push(T element)
element - The new elementList instance, containing the new element on top of this Listdefault List<T> push(T... elements)
elements - Elements, may be emptyList instance, containing the new elements on top of this ListNullPointerException - if elements is nulldefault List<T> pushAll(Iterable<T> elements)
elements - An Iterable of elements, may be emptyList instance, containing the new elements on top of this ListNullPointerException - if elements is nulldefault List<T> remove(T element)
Seqdefault List<T> removeFirst(Predicate<T> predicate)
SeqremoveFirst in interface LinearSeq<T>removeFirst in interface Seq<T>predicate - an predicatedefault List<T> removeLast(Predicate<T> predicate)
SeqremoveLast in interface LinearSeq<T>removeLast in interface Seq<T>predicate - an predicatedefault List<T> removeAt(int index)
Seqdefault List<T> removeAll(T element)
Seqdefault List<T> removeAll(Iterable<? extends T> elements)
Seq@Deprecated default List<T> removeAll(Predicate<? super T> predicate)
Seqdefault List<T> replace(T currentElement, T newElement)
Traversablereplace in interface LinearSeq<T>replace in interface Seq<T>replace in interface Traversable<T>currentElement - An element to be substituted.newElement - A replacement for currentElement.default List<T> replaceAll(T currentElement, T newElement)
TraversablereplaceAll in interface LinearSeq<T>replaceAll in interface Seq<T>replaceAll in interface Traversable<T>currentElement - An element to be substituted.newElement - A replacement for currentElement.default List<T> retainAll(Iterable<? extends T> elements)
Traversabledefault List<T> reverse()
Seqdefault List<T> rotateLeft(int n)
Seq
// = List(3, 4, 5, 1, 2)
List.of(1, 2, 3, 4, 5).rotateLeft(2);
rotateLeft in interface LinearSeq<T>rotateLeft in interface Seq<T>n - distance of left rotationdefault List<T> rotateRight(int n)
Seq
// = List(4, 5, 1, 2, 3)
List.of(1, 2, 3, 4, 5).rotateRight(2);
rotateRight in interface LinearSeq<T>rotateRight in interface Seq<T>n - distance of right rotationdefault List<T> scan(T zero, BiFunction<? super T,? super T,? extends T> operation)
Traversablescan in interface LinearSeq<T>scan in interface Seq<T>scan in interface Traversable<T>zero - neutral element for the operator opoperation - the associative operator for the scandefault <U> List<U> scanLeft(U zero, BiFunction<? super U,? super T,? extends U> operation)
TraversablescanLeft in interface LinearSeq<T>scanLeft in interface Seq<T>scanLeft in interface Traversable<T>U - the type of the elements in the resulting collectionzero - the initial valueoperation - the binary operator applied to the intermediate result and the elementdefault <U> List<U> scanRight(U zero, BiFunction<? super T,? super U,? extends U> operation)
TraversablescanRight in interface LinearSeq<T>scanRight in interface Seq<T>scanRight in interface Traversable<T>U - the type of the elements in the resulting collectionzero - the initial valueoperation - the binary operator applied to the intermediate result and the elementdefault List<T> shuffle()
Seqdefault List<T> slice(int beginIndex, int endIndex)
SeqbeginIndex and extends to the element at index endIndex - 1.
Examples:
List.of(1, 2, 3, 4).slice(1, 3); // = (2, 3)
List.of(1, 2, 3, 4).slice(0, 4); // = (1, 2, 3, 4)
List.of(1, 2, 3, 4).slice(2, 2); // = ()
List.of(1, 2).slice(1, 0); // = ()
List.of(1, 2).slice(-10, 10); // = (1, 2)
See also Seq.subSequence(int, int) which throws in some cases instead of returning a sequence.default Iterator<List<T>> slideBy(Function<? super T,?> classifier)
TraversableTraversable.
Each window contains elements with the same class, as determined by classifier. Two consecutive
values in this Traversable will be in the same window only if classifier returns equal
values for them. Otherwise, the values will constitute the last element of the previous window and the
first element of the next window.
Examples:
[].slideBy(Function.identity()) = []
[1,2,3,4,4,5].slideBy(Function.identity()) = [[1],[2],[3],[4,4],[5]]
[1,2,3,10,12,5,7,20,29].slideBy(x -> x/10) = [[1,2,3],[10,12],[5,7],[20,29]]
default Iterator<List<T>> sliding(int size)
Traversablesize and step size 1 over this Traversable by calling
Traversable.sliding(int, int).default Iterator<List<T>> sliding(int size, int step)
Traversablesize and step size over this Traversable.
Examples:
[].sliding(1,1) = []
[1,2,3,4,5].sliding(2,3) = [[1,2],[4,5]]
[1,2,3,4,5].sliding(2,4) = [[1,2],[5]]
[1,2,3,4,5].sliding(2,5) = [[1,2]]
[1,2,3,4].sliding(5,3) = [[1,2,3,4],[4]]
default List<T> sorted()
SeqComparable, a java.lang.ClassCastException may be thrown.default List<T> sorted(Comparator<? super T> comparator)
SeqComparator. If this elements are not
Comparable, a java.lang.ClassCastException may be thrown.default <U extends Comparable<? super U>> List<T> sortBy(Function<? super T,? extends U> mapper)
Seqmapper.default <U> List<T> sortBy(Comparator<? super U> comparator, Function<? super T,? extends U> mapper)
Seqmapper.default Tuple2<List<T>,List<T>> span(Predicate<? super T> predicate)
Traversablepredicate and the second element is the remainder.default Tuple2<List<T>,List<T>> splitAt(int n)
SeqsplitAt(n) is equivalent to
Tuple.of(take(n), drop(n)).default Tuple2<List<T>,List<T>> splitAt(Predicate<? super T> predicate)
SeqPredicate, e.g. Tuple(init, element+tail).default Tuple2<List<T>,List<T>> splitAtInclusive(Predicate<? super T> predicate)
SeqPredicate, e.g. Tuple(init+element, tail).splitAtInclusive in interface Seq<T>predicate - An predicateTuple containing divided sequencesdefault String stringPrefix()
ValuestringPrefix in interface Value<T>default List<T> subSequence(int beginIndex)
SeqbeginIndex and extends to the end of this Seq.
Examples:
List.of(1, 2).subSequence(0); // = (1, 2)
List.of(1, 2).subSequence(1); // = (2)
List.of(1, 2).subSequence(2); // = ()
List.of(1, 2).subSequence(10); // throws IndexOutOfBoundsException
List.of(1, 2).subSequence(-10); // throws IndexOutOfBoundsException
See also Seq.drop(int) which is similar but does not throw.subSequence in interface LinearSeq<T>subSequence in interface Seq<T>beginIndex - the beginning index, inclusivedefault List<T> subSequence(int beginIndex, int endIndex)
SeqbeginIndex and extends to the element at index endIndex - 1.
Examples:
List.of(1, 2, 3, 4).subSequence(1, 3); // = (2, 3)
List.of(1, 2, 3, 4).subSequence(0, 4); // = (1, 2, 3, 4)
List.of(1, 2, 3, 4).subSequence(2, 2); // = ()
List.of(1, 2).subSequence(1, 0); // throws IndexOutOfBoundsException
List.of(1, 2).subSequence(-10, 1); // throws IndexOutOfBoundsException
List.of(1, 2).subSequence(0, 10); // throws IndexOutOfBoundsException
See also Seq.slice(int, int) which returns an empty sequence instead of throwing.subSequence in interface LinearSeq<T>subSequence in interface Seq<T>beginIndex - the beginning index, inclusiveendIndex - the end index, exclusiveList<T> tail()
Traversabledefault Option<List<T>> tailOption()
TraversableOption.tailOption in interface LinearSeq<T>tailOption in interface Seq<T>tailOption in interface Traversable<T>Some(traversable) or None if this is empty.default List<T> take(int n)
Traversable
The result is equivalent to sublist(0, max(0, min(length(), n))) but does not throw if n < 0 or
n > length().
In the case of n < 0 the empty instance is returned, in the case of n > length() this is returned.
default List<T> takeUntil(Predicate<? super T> predicate)
Traversable
Note: This is essentially the same as takeWhile(predicate.negate()). It is intended to be used with
method references, which cannot be negated directly.
takeUntil in interface LinearSeq<T>takeUntil in interface Seq<T>takeUntil in interface Traversable<T>predicate - A condition tested subsequently for this elements.default List<T> takeWhile(Predicate<? super T> predicate)
TraversabletakeWhile in interface LinearSeq<T>takeWhile in interface Seq<T>takeWhile in interface Traversable<T>predicate - A condition tested subsequently for the contained elements.default List<T> takeRight(int n)
Traversable
The result is equivalent to sublist(max(0, min(length(), length() - n)), n), i.e. takeRight will not
throw if n < 0 or n > length().
In the case of n < 0 the empty instance is returned, in the case of n > length() this is returned.
takeRight in interface LinearSeq<T>takeRight in interface Seq<T>takeRight in interface Traversable<T>n - The number of elements to take.default List<T> takeRightUntil(Predicate<? super T> predicate)
SeqtakeRightUntil in interface LinearSeq<T>takeRightUntil in interface Seq<T>predicate - A condition tested subsequently for this elements, starting from the end.default List<T> takeRightWhile(Predicate<? super T> predicate)
Seq
Note: This is essentially the same as takeRightUntil(predicate.negate()).
It is intended to be used with method references, which cannot be negated directly.
takeRightWhile in interface LinearSeq<T>takeRightWhile in interface Seq<T>predicate - A condition tested subsequently for this elements, starting from the end.default <U> U transform(Function<? super List<T>,? extends U> f)
List.U - Type of transformation resultf - A transformationUNullPointerException - if f is nulldefault <T1,T2> Tuple2<List<T1>,List<T2>> unzip(Function<? super T,Tuple2<? extends T1,? extends T2>> unzipper)
Traversableunzip in interface LinearSeq<T>unzip in interface Seq<T>unzip in interface Traversable<T>T1 - 1st element type of a pair returned by unzipperT2 - 2nd element type of a pair returned by unzipperunzipper - a function which converts elements of this to pairsdefault <T1,T2,T3> Tuple3<List<T1>,List<T2>,List<T3>> unzip3(Function<? super T,Tuple3<? extends T1,? extends T2,? extends T3>> unzipper)
Traversableunzip3 in interface Seq<T>unzip3 in interface Traversable<T>T1 - 1st element type of a triplet returned by unzipperT2 - 2nd element type of a triplet returned by unzipperT3 - 3rd element type of a triplet returned by unzipperunzipper - a function which converts elements of this to pairsdefault List<T> update(int index, T element)
Seqdefault List<T> update(int index, Function<? super T,? extends T> updater)
Seqdefault <U> List<Tuple2<T,U>> zip(Iterable<? extends U> that)
Traversable
The length of the returned traversable is the minimum of the lengths of this traversable and that
iterable.
zip in interface LinearSeq<T>zip in interface Seq<T>zip in interface Traversable<T>U - The type of the second half of the returned pairs.that - The Iterable providing the second half of each result pair.that iterable.default <U,R> List<R> zipWith(Iterable<? extends U> that, BiFunction<? super T,? super U,? extends R> mapper)
Traversable
The length of the returned traversable is the minimum of the lengths of this traversable and that
iterable.
zipWith in interface LinearSeq<T>zipWith in interface Seq<T>zipWith in interface Traversable<T>U - The type of the second parameter of the mapper.R - The type of the mapped elements.that - The Iterable providing the second parameter of the mapper.mapper - a mapper.that iterable.default <U> List<Tuple2<T,U>> zipAll(Iterable<? extends U> that, T thisElem, U thatElem)
Traversable
The length of the returned traversable is the maximum of the lengths of this traversable and that
iterable.
Special case: if this traversable is shorter than that elements, and that elements contains duplicates, the resulting traversable may be shorter than the maximum of the lengths of this and that because a traversable contains an element at most once.
If this Traversable is shorter than that, thisElem values are used to fill the result. If that is shorter than this Traversable, thatElem values are used to fill the result.
zipAll in interface LinearSeq<T>zipAll in interface Seq<T>zipAll in interface Traversable<T>U - The type of the second half of the returned pairs.that - The Iterable providing the second half of each result pair.thisElem - The element to be used to fill up the result if this traversable is shorter than that.thatElem - The element to be used to fill up the result if that is shorter than this traversable.default List<Tuple2<T,Integer>> zipWithIndex()
TraversablezipWithIndex in interface LinearSeq<T>zipWithIndex in interface Seq<T>zipWithIndex in interface Traversable<T>default <U> List<U> zipWithIndex(BiFunction<? super T,? super Integer,? extends U> mapper)
Traversable
The length of the returned traversable is the minimum of the lengths of this traversable and that
iterable.
zipWithIndex in interface LinearSeq<T>zipWithIndex in interface Seq<T>zipWithIndex in interface Traversable<T>U - The type of the mapped elements.mapper - a mapper.that iterable.Copyright © 2021. All Rights Reserved.