package immutable
- Alphabetic
- Public
- All
Type Members
-
final
case class
::[B](head: B, tl: List[B]) extends List[B] with Product with Serializable
A non empty list characterized by a head and a tail.
A non empty list characterized by a head and a tail.
- B
the type of the list elements.
- head
the first element of the list
- tl
the list containing the remaining elements of this list after the first one.
- Annotations
- @SerialVersionUID()
- Version
1.0, 15/07/2003
- Since
2.8
-
abstract
class
AbstractMap[K, +V] extends collection.AbstractMap[K, V] with Map[K, V]
Explicit instantiation of the
Map
trait to reduce class file size in subclasses. -
abstract
class
BitSet extends AbstractSet[Int] with SortedSet[Int] with collection.BitSet with BitSetLike[BitSet] with Serializable
A class for immutable bitsets.
A class for immutable bitsets.
Bitsets are sets of non-negative integers which are represented as variable-size arrays of bits packed into 64-bit words. The memory footprint of a bitset is determined by the largest number stored in it.
- Annotations
- @SerialVersionUID()
- See also
Collection Library overview" section on
Immutable BitSets
for more information.
-
trait
DefaultMap[A, +B] extends Map[A, B]
A default map which implements the
+
and-
methods of maps.A default map which implements the
+
and-
methods of maps. It does so using the default builder for maps defined in theMap
object. Instances that inherit fromDefaultMap[A, B]
still have to define:def get(key: A): Option[B] def iterator: Iterator[(A, B)]
It refers back to the original map.
It might also be advisable to override
foreach
orsize
if efficient implementations can be found.- A
the type of the keys contained in this map.
- B
the type of the values associated with the keys.
- Since
2.8
-
sealed
class
HashMap[A, +B] extends AbstractMap[A, B] with Map[A, B] with MapLike[A, B, HashMap[A, B]] with Serializable with CustomParallelizable[(A, B), ParHashMap[A, B]]
This class implements immutable maps using a hash trie.
This class implements immutable maps using a hash trie.
Note: The builder of this hash map may return specialized representations for small maps.
- A
the type of the keys contained in this hash map.
- B
the type of the values associated with the keys.
- Annotations
- @SerialVersionUID()
- Version
2.8
- Since
2.3
- See also
"Scala's Collection Library overview" section on
Hash Tries
for more information.
-
sealed
class
HashSet[A] extends AbstractSet[A] with Set[A] with GenericSetTemplate[A, HashSet] with SetLike[A, HashSet[A]] with CustomParallelizable[A, ParHashSet[A]] with Serializable
This class implements immutable sets using a hash trie.
This class implements immutable sets using a hash trie.
Note: The builder of this hash set may return specialized representations for small sets.
- A
the type of the elements contained in this hash set.
- Annotations
- @SerialVersionUID()
- Version
2.8
- Since
2.3
-
trait
IndexedSeq[+A] extends Seq[A] with collection.IndexedSeq[A] with GenericTraversableTemplate[A, IndexedSeq] with IndexedSeqLike[A, IndexedSeq[A]]
A subtrait of
collection.IndexedSeq
which represents indexed sequences that are guaranteed immutable.A subtrait of
collection.IndexedSeq
which represents indexed sequences that are guaranteed immutable.Indexed sequences support constant-time or near constant-time element access and length computation. They are defined in terms of abstract methods
apply
for indexing andlength
.Indexed sequences do not add any new methods to
Seq
, but promise efficient implementations of random access patterns. -
sealed abstract
class
IntMap[+T] extends AbstractMap[immutable.IntMapUtils.Int, T] with Map[immutable.IntMapUtils.Int, T] with MapLike[immutable.IntMapUtils.Int, T, IntMap[T]]
Specialised immutable map structure for integer keys, based on Fast Mergeable Integer Maps by Okasaki and Gill.
Specialised immutable map structure for integer keys, based on Fast Mergeable Integer Maps by Okasaki and Gill. Essentially a trie based on binary digits of the integers.
Note: This class is as of 2.8 largely superseded by HashMap.
- T
type of the values associated with integer keys.
- Since
2.7
-
trait
Iterable[+A] extends Traversable[A] with collection.Iterable[A] with GenericTraversableTemplate[A, Iterable] with IterableLike[A, Iterable[A]] with Parallelizable[A, ParIterable[A]]
A base trait for iterable collections that are guaranteed immutable.
A base trait for iterable collections that are guaranteed immutable.
This is a base trait for all immutable Scala collections that define an
iterator
method to step through one-by-one the collection's elements. Implementations of this trait need to provide a concrete method with signature:def iterator: Iterator[A]
They also need to provide a method
newBuilder
which creates a builder for collections of the same kind.This trait implements
Iterable
'sforeach
method by stepping through all elements usingiterator
. Subclasses should re-implementforeach
with something more efficient, if possible.This trait adds methods
iterator
,sameElements
,takeRight
,dropRight
to the methods inherited from trait `Traversable`.Note: This trait replaces every method that uses
break
inTraversableLike
by an iterator version. -
trait
LinearSeq[+A] extends Seq[A] with collection.LinearSeq[A] with GenericTraversableTemplate[A, LinearSeq] with LinearSeqLike[A, LinearSeq[A]]
A subtrait of
collection.LinearSeq
which represents sequences that are guaranteed immutable.A subtrait of
collection.LinearSeq
which represents sequences that are guaranteed immutable.Linear sequences have reasonably efficient
head
,tail
, andisEmpty
methods. If these methods provide the fastest way to traverse the collection, a collectionColl
that extends this trait should also extendLinearSeqOptimized[A, Coll[A]]
. -
sealed abstract
class
List[+A] extends AbstractSeq[A] with LinearSeq[A] with Product with GenericTraversableTemplate[A, List] with LinearSeqOptimized[A, List[A]] with Serializable
A class for immutable linked lists representing ordered collections of elements of type
A
.A class for immutable linked lists representing ordered collections of elements of type
A
.This class comes with two implementing case classes
scala.Nil
andscala.::
that implement the abstract membersisEmpty
,head
andtail
.This class is optimal for last-in-first-out (LIFO), stack-like access patterns. If you need another access pattern, for example, random access or FIFO, consider using a collection more suited to this than
List
.Note: Despite being an immutable collection, the implementation uses mutable state internally during construction. These state changes are invisible in single-threaded code but can lead to race conditions in some multi-threaded scenarios. The state of a new collection instance may not have been "published" (in the sense of the Java Memory Model specification), so that an unsynchronized non-volatile read from another thread may observe the object in an invalid state (see scala/bug#7838 for details). Note that such a read is not guaranteed to ever see the written object at all, and should therefore not be used, regardless of this issue. The easiest workaround is to exchange values between threads through a volatile var.
Performance
Time:
List
hasO(1)
prepend and head/tail access. Most other operations areO(n)
on the number of elements in the list. This includes the index-based lookup of elements,length
,append
andreverse
.Space:
List
implements structural sharing of the tail list. This means that many operations are either zero- or constant-memory cost.val mainList = List(3, 2, 1) val with4 = 4 :: mainList // re-uses mainList, costs one :: instance val with42 = 42 :: mainList // also re-uses mainList, cost one :: instance val shorter = mainList.tail // costs nothing as it uses the same 2::1::Nil instances as mainList
- Annotations
- @SerialVersionUID()
// Make a list via the companion object factory val days = List("Sunday", "Monday", "Tuesday", "Wednesday", "Thursday", "Friday", "Saturday") // Make a list element-by-element val when = "AM" :: "PM" :: List() // Pattern match days match { case firstDay :: otherDays => println("The first day of the week is: " + firstDay) case List() => println("There don't seem to be any week days.") }
- Version
2.8
- Since
1.0
- Note
The functional list is characterized by persistence and structural sharing, thus offering considerable performance and space consumption benefits in some scenarios if used correctly. However, note that objects having multiple references into the same functional list (that is, objects that rely on structural sharing), will be serialized and deserialized with multiple lists, one for each reference to it. I.e. structural sharing is lost after serialization/deserialization.
- See also
"Scala's Collection Library overview" section on
Lists
for more information.
Example: -
sealed
class
ListMap[A, +B] extends AbstractMap[A, B] with Map[A, B] with MapLike[A, B, ListMap[A, B]] with Serializable
This class implements immutable maps using a list-based data structure.
This class implements immutable maps using a list-based data structure. List map iterators and traversal methods visit key-value pairs in the order whey were first inserted.
Entries are stored internally in reversed insertion order, which means the newest key is at the head of the list. As such, methods such as
head
andtail
are O(n), whilelast
andinit
are O(1). Other operations, such as inserting or removing entries, are also O(n), which makes this collection suitable only for a small number of elements.Instances of
ListMap
represent empty maps; they can be either created by calling the constructor directly, or by applying the functionListMap.empty
.- A
the type of the keys contained in this list map
- B
the type of the values associated with the keys
- Annotations
- @SerialVersionUID()
- Version
2.0, 01/01/2007
- Since
1
-
sealed
class
ListSet[A] extends AbstractSet[A] with Set[A] with GenericSetTemplate[A, ListSet] with SetLike[A, ListSet[A]] with Serializable
This class implements immutable sets using a list-based data structure.
This class implements immutable sets using a list-based data structure. List set iterators and traversal methods visit elements in the order whey were first inserted.
Elements are stored internally in reversed insertion order, which means the newest element is at the head of the list. As such, methods such as
head
andtail
are O(n), whilelast
andinit
are O(1). Other operations, such as inserting or removing entries, are also O(n), which makes this collection suitable only for a small number of elements.Instances of
ListSet
represent empty sets; they can be either created by calling the constructor directly, or by applying the functionListSet.empty
.- A
the type of the elements contained in this list set
- Annotations
- @SerialVersionUID()
- Version
1.0, 09/07/2003
- Since
1
-
sealed abstract
class
LongMap[+T] extends AbstractMap[immutable.LongMapUtils.Long, T] with Map[immutable.LongMapUtils.Long, T] with MapLike[immutable.LongMapUtils.Long, T, LongMap[T]]
Specialised immutable map structure for long keys, based on Fast Mergeable Long Maps by Okasaki and Gill.
Specialised immutable map structure for long keys, based on Fast Mergeable Long Maps by Okasaki and Gill. Essentially a trie based on binary digits of the integers.
Note: This class is as of 2.8 largely superseded by HashMap.
- T
type of the values associated with the long keys.
- Since
2.7
-
trait
Map[K, +V] extends Iterable[(K, V)] with collection.Map[K, V] with MapLike[K, V, Map[K, V]]
A generic trait for immutable maps.
A generic trait for immutable maps. Concrete classes have to provide functionality for the abstract methods in
Map
:def get(key: K): Option[V] def iterator: Iterator[(K, V)] def + [V1 >: V](kv: (K, V1)): Map[K, V1] def -(key: K): Map[K, V]
- Since
1
-
trait
MapLike[K, +V, +This <: MapLike[K, V, This] with Map[K, V]] extends collection.MapLike[K, V, This] with Parallelizable[(K, V), ParMap[K, V]]
A generic template for immutable maps from keys of type
K
to values of typeV
.A generic template for immutable maps from keys of type
K
to values of typeV
. To implement a concrete map, you need to provide implementations of the following methods (whereThis
is the type of the actual map implementation):def get(key: K): Option[V] def iterator: Iterator[(K, V)] def + [V1 >: V](kv: (K, V)): Map[K, V1] def - (key: K): This
If you wish that transformer methods like
take
,drop
,filter
return the same kind of map, you should also override:def empty: This
It is also good idea to override methods
foreach
andsize
for efficiency.- K
the type of the keys contained in this collection.
- V
the type of the values associated with the keys.
- This
The type of the actual map implementation.
- Version
2.8
- Since
2.8
-
abstract
class
NumericRange[T] extends AbstractSeq[T] with IndexedSeq[T] with Serializable
NumericRange
is a more generic version of theRange
class which works with arbitrary types.NumericRange
is a more generic version of theRange
class which works with arbitrary types. It must be supplied with anIntegral
implementation of the range type.Factories for likely types include
Range.BigInt
,Range.Long
, andRange.BigDecimal
.Range.Int
exists for completeness, but theInt
-basedscala.Range
should be more performant.val r1 = new Range(0, 100, 1) val veryBig = Int.MaxValue.toLong + 1 val r2 = Range.Long(veryBig, veryBig + 100, 1) assert(r1 sameElements r2.map(_ - veryBig))
- Version
2.8
-
sealed
class
Queue[+A] extends AbstractSeq[A] with LinearSeq[A] with GenericTraversableTemplate[A, Queue] with LinearSeqLike[A, Queue[A]] with Serializable
Queue
objects implement data structures that allow to insert and retrieve elements in a first-in-first-out (FIFO) manner.Queue
objects implement data structures that allow to insert and retrieve elements in a first-in-first-out (FIFO) manner.Queue
is implemented as a pair ofList
s, one containing the in elements and the other the out elements. Elements are added to the in list and removed from the out list. When the out list runs dry, the queue is pivoted by replacing the out list by in.reverse, and in by Nil.Adding items to the queue always has cost
O(1)
. Removing items has costO(1)
, except in the case where a pivot is required, in which case, a cost ofO(n)
is incurred, wheren
is the number of elements in the queue. When this happens,n
remove operations withO(1)
cost are guaranteed. Removing an item is on averageO(1)
.- Annotations
- @SerialVersionUID()
- Version
1.0, 08/07/2003
- Since
1
- See also
"Scala's Collection Library overview" section on
Immutable Queues
for more information.
-
sealed
class
Range extends AbstractSeq[Int] with IndexedSeq[Int] with CustomParallelizable[Int, ParRange] with Serializable
The
Range
class represents integer values in range [start;end) with non-zero step valuestep
.The
Range
class represents integer values in range [start;end) with non-zero step valuestep
. It's a special case of an indexed sequence. For example:val r1 = 0 until 10 val r2 = r1.start until r1.end by r1.step + 1 println(r2.length) // = 5
Ranges that contain more than
Int.MaxValue
elements can be created, but these overfull ranges have only limited capabilities. Any method that could require a collection of overInt.MaxValue
length to be created, or could be asked to index beyondInt.MaxValue
elements will throw an exception. Overfull ranges can safely be reduced in size by changing the step size (e.g.by 3
) or taking/dropping elements.contains
,equals
, and access to the ends of the range (head
,last
,tail
,init
) are also permitted on overfull ranges.- Annotations
- @SerialVersionUID()
- Version
2.8
- Since
2.5
- See also
"Scala's Collection Library overview" section on
Ranges
for more information.
-
trait
Seq[+A] extends Iterable[A] with collection.Seq[A] with GenericTraversableTemplate[A, Seq] with SeqLike[A, Seq[A]] with Parallelizable[A, ParSeq[A]]
A subtrait of
collection.Seq
which represents sequences that are guaranteed immutable.A subtrait of
collection.Seq
which represents sequences that are guaranteed immutable.Sequences are special cases of iterable collections of class
Iterable
. Unlike iterables, sequences always have a defined order of elements. Sequences provide a methodapply
for indexing. Indices range from0
up to thelength
of a sequence. Sequences support a number of methods to find occurrences of elements or subsequences, includingsegmentLength
,prefixLength
,indexWhere
,indexOf
,lastIndexWhere
,lastIndexOf
,startsWith
,endsWith
,indexOfSlice
.Another way to see a sequence is as a
PartialFunction
fromInt
values to the element type of the sequence. TheisDefinedAt
method of a sequence returnstrue
for the interval from0
untillength
.Sequences can be accessed in reverse order of their elements, using methods
reverse
andreverseIterator
.Sequences have two principal subtraits,
IndexedSeq
andLinearSeq
, which give different guarantees for performance. AnIndexedSeq
provides fast random-access of elements and a fastlength
operation. ALinearSeq
provides fast access only to the first element viahead
, but also has a fasttail
operation. -
trait
Set[A] extends Iterable[A] with collection.Set[A] with GenericSetTemplate[A, Set] with SetLike[A, Set[A]] with Parallelizable[A, ParSet[A]]
A generic trait for immutable sets.
A generic trait for immutable sets.
A set is a collection that contains no duplicate elements.
To implement a concrete set, you need to provide implementations of the following methods:
def contains(key: A): Boolean def iterator: Iterator[A] def +(elem: A): This def -(elem: A): This
If you wish that methods like
take
,drop
,filter
return the same kind of set, you should also override:def empty: This
It is also good idea to override methods
foreach
andsize
for efficiency.- Since
1.0
-
trait
SortedMap[A, +B] extends Map[A, B] with collection.SortedMap[A, B] with MapLike[A, B, SortedMap[A, B]] with SortedMapLike[A, B, SortedMap[A, B]]
A map whose keys are sorted.
A map whose keys are sorted.
- A
the type of the keys contained in this sorted map.
- B
the type of the values associated with the keys.
- Version
2.8
- Since
2.4
-
trait
SortedSet[A] extends Set[A] with collection.SortedSet[A] with SortedSetLike[A, SortedSet[A]]
A subtrait of
collection.SortedSet
which represents sorted sets which cannot be mutated.A subtrait of
collection.SortedSet
which represents sorted sets which cannot be mutated.- Version
2.8
- Since
2.4
-
sealed abstract
class
Stream[+A] extends AbstractSeq[A] with LinearSeq[A] with GenericTraversableTemplate[A, Stream] with LinearSeqOptimized[A, Stream[A]] with Serializable
The class
Stream
implements lazy lists where elements are only evaluated when they are needed.The class
Stream
implements lazy lists where elements are only evaluated when they are needed. Here is an example:import scala.math.BigInt object Main extends App { lazy val fibs: Stream[BigInt] = BigInt(0) #:: BigInt(1) #:: fibs.zip(fibs.tail).map { n => n._1 + n._2 } fibs take 5 foreach println } // prints // // 0 // 1 // 1 // 2 // 3
The
Stream
class also employs memoization such that previously computed values are converted fromStream
elements to concrete values of typeA
. To illustrate, we will alter body of thefibs
value above and take some more values:import scala.math.BigInt object Main extends App { lazy val fibs: Stream[BigInt] = BigInt(0) #:: BigInt(1) #:: fibs.zip( fibs.tail).map(n => { println("Adding %d and %d".format(n._1, n._2)) n._1 + n._2 }) fibs take 5 foreach println fibs take 6 foreach println } // prints // // 0 // 1 // Adding 0 and 1 // 1 // Adding 1 and 1 // 2 // Adding 1 and 2 // 3 // And then prints // // 0 // 1 // 1 // 2 // 3 // Adding 2 and 3 // 5
There are a number of subtle points to the above example.
- The definition of
fibs
is aval
not a method. The memoization of theStream
requires us to have somewhere to store the information and aval
allows us to do that. - While the
Stream
is actually being modified during access, this does not change the notion of its immutability. Once the values are memoized they do not change and values that have yet to be memoized still "exist", they simply haven't been realized yet. - One must be cautious of memoization; you can very quickly eat up large
amounts of memory if you're not careful. The reason for this is that the
memoization of the
Stream
creates a structure much like scala.collection.immutable.List. So long as something is holding on to the head, the head holds on to the tail, and so it continues recursively. If, on the other hand, there is nothing holding on to the head (e.g. we useddef
to define theStream
) then once it is no longer being used directly, it disappears. - Note that some operations, including drop, dropWhile,
flatMap or collect may process a large number of intermediate
elements before returning. These necessarily hold onto the head, since
they are methods on
Stream
, and a stream holds its own head. For computations of this sort where memoization is not desired, useIterator
when possible.
// For example, let's build the natural numbers and do some silly iteration // over them. // We'll start with a silly iteration def loop(s: String, i: Int, iter: Iterator[Int]): Unit = { // Stop after 200,000 if (i < 200001) { if (i % 50000 == 0) println(s + i) loop(s, iter.next, iter) } } // Our first Stream definition will be a val definition val stream1: Stream[Int] = { def loop(v: Int): Stream[Int] = v #:: loop(v + 1) loop(0) } // Because stream1 is a val, everything that the iterator produces is held // by virtue of the fact that the head of the Stream is held in stream1 val it1 = stream1.iterator loop("Iterator1: ", it1.next, it1) // We can redefine this Stream such that all we have is the Iterator left // and allow the Stream to be garbage collected as required. Using a def // to provide the Stream ensures that no val is holding onto the head as // is the case with stream1 def stream2: Stream[Int] = { def loop(v: Int): Stream[Int] = v #:: loop(v + 1) loop(0) } val it2 = stream2.iterator loop("Iterator2: ", it2.next, it2) // And, of course, we don't actually need a Stream at all for such a simple // problem. There's no reason to use a Stream if you don't actually need // one. val it3 = new Iterator[Int] { var i = -1 def hasNext = true def next(): Int = { i += 1; i } } loop("Iterator3: ", it3.next, it3)
- The fact that
tail
works at all is of interest. In the definition offibs
we have an initial(0, 1, Stream(...))
sotail
is deterministic. If we definedfibs
such that only0
were concretely known then the act of determiningtail
would require the evaluation oftail
which would cause an infinite recursion and stack overflow. If we define a definition where the tail is not initially computable then we're going to have an infinite recursion:
// The first time we try to access the tail we're going to need more // information which will require us to recurse, which will require us to // recurse, which... lazy val sov: Stream[Vector[Int]] = Vector(0) #:: sov.zip(sov.tail).map { n => n._1 ++ n._2 }
The definition of
fibs
above creates a larger number of objects than necessary depending on how you might want to implement it. The following implementation provides a more "cost effective" implementation due to the fact that it has a more direct route to the numbers themselves:lazy val fib: Stream[Int] = { def loop(h: Int, n: Int): Stream[Int] = h #:: loop(n, h + n) loop(1, 1) }
Note that
mkString
forces evaluation of aStream
, butaddString
does not. In both cases, aStream
that is or ends in a cycle (e.g.lazy val s: Stream[Int] = 0 #:: s
) will convert additional trips through the cycle to...
. Additionally,addString
will display an un-memoized tail as?
.- A
the type of the elements contained in this stream.
- Version
1.1 08/08/03
- Since
2.8
- See also
"Scala's Collection Library overview" section on
Streams
for more information.
- The definition of
-
final
class
StreamIterator[+A] extends AbstractIterator[A] with Iterator[A]
A specialized, extra-lazy implementation of a stream iterator, so it can iterate as lazily as it traverses the tail.
- trait StreamView[+A, +Coll] extends StreamViewLike[A, Coll, StreamView[A, Coll]]
- trait StreamViewLike[+A, +Coll, +This <: StreamView[A, Coll] with StreamViewLike[A, Coll, This]] extends SeqView[A, Coll] with SeqViewLike[A, Coll, This]
-
trait
StringLike[+Repr] extends IndexedSeqOptimized[Char, Repr] with Ordered[String]
A trait describing stringlike collections.
A trait describing stringlike collections.
- Repr
The type of the actual collection inheriting
StringLike
.
- Since
2.8
-
final
class
StringOps extends AnyVal with StringLike[String]
This class serves as a wrapper providing scala.Predef.Strings with all the operations found in indexed sequences.
This class serves as a wrapper providing scala.Predef.Strings with all the operations found in indexed sequences. Where needed,
String
s are implicitly converted into instances of this class.The difference between this class and
WrappedString
is that calling transformer methods such asfilter
andmap
will yield aString
object, whereas aWrappedString
will remain aWrappedString
.- Since
2.8
-
trait
Traversable[+A] extends collection.Traversable[A] with GenericTraversableTemplate[A, Traversable] with TraversableLike[A, Traversable[A]] with Immutable
A trait for traversable collections that are guaranteed immutable.
A trait for traversable collections that are guaranteed immutable.
This is a base trait of all kinds of immutable Scala collections. It implements the behavior common to all collections, in terms of a method
foreach
with signature:def foreach[U](f: Elem => U): Unit
Collection classes mixing in this trait provide a concrete
foreach
method which traverses all the elements contained in the collection, applying a given function to each. They also need to provide a methodnewBuilder
which creates a builder for collections of the same kind.A traversable class might or might not have two properties: strictness and orderedness. Neither is represented as a type.
The instances of a strict collection class have all their elements computed before they can be used as values. By contrast, instances of a non-strict collection class may defer computation of some of their elements until after the instance is available as a value. A typical example of a non-strict collection class is a scala.collection.immutable.Stream. A more general class of examples are
TraversableViews
.If a collection is an instance of an ordered collection class, traversing its elements with
foreach
will always visit elements in the same order, even for different runs of the program. If the class is not ordered,foreach
can visit elements in different orders for different runs (but it will keep the same order in the same run).'A typical example of a collection class which is not ordered is a
HashMap
of objects. The traversal order for hash maps will depend on the hash codes of its elements, and these hash codes might differ from one run to the next. By contrast, aLinkedHashMap
is ordered because itsforeach
method visits elements in the order they were inserted into theHashMap
. -
final
class
TreeMap[A, +B] extends SortedMap[A, B] with SortedMapLike[A, B, TreeMap[A, B]] with MapLike[A, B, TreeMap[A, B]] with Serializable
This class implements immutable maps using a tree.
This class implements immutable maps using a tree.
- A
the type of the keys contained in this tree map.
- B
the type of the values associated with the keys.
- Version
1.1, 03/05/2004
- Since
1
- See also
"Scala's Collection Library overview" section on
Red-Black Trees
for more information.
-
final
class
TreeSet[A] extends SortedSet[A] with SortedSetLike[A, TreeSet[A]] with Serializable
This class implements immutable sets using a tree.
This class implements immutable sets using a tree.
- A
the type of the elements contained in this tree set
- Annotations
- @SerialVersionUID()
- Version
2.0, 02/01/2007
- Since
1
- See also
"Scala's Collection Library overview" section on
Red-Black Trees
for more information.
-
final
class
Vector[+A] extends AbstractSeq[A] with IndexedSeq[A] with GenericTraversableTemplate[A, Vector] with IndexedSeqLike[A, Vector[A]] with VectorPointer[A] with Serializable with CustomParallelizable[A, ParVector[A]]
Vector is a general-purpose, immutable data structure.
Vector is a general-purpose, immutable data structure. It provides random access and updates in effectively constant time, as well as very fast append and prepend. Because vectors strike a good balance between fast random selections and fast random functional updates, they are currently the default implementation of immutable indexed sequences. It is backed by a little endian bit-mapped vector trie with a branching factor of 32. Locality is very good, but not contiguous, which is good for very large sequences.
Note: Despite being an immutable collection, the implementation uses mutable state internally during construction. These state changes are invisible in single-threaded code but can lead to race conditions in some multi-threaded scenarios. The state of a new collection instance may not have been "published" (in the sense of the Java Memory Model specification), so that an unsynchronized non-volatile read from another thread may observe the object in an invalid state (see scala/bug#7838 for details). Note that such a read is not guaranteed to ever see the written object at all, and should therefore not be used, regardless of this issue. The easiest workaround is to exchange values between threads through a volatile var.
- A
the element type
- Annotations
- @SerialVersionUID()
- See also
"Scala's Collection Library overview" section on
Vectors
for more information.
-
final
class
VectorBuilder[A] extends ReusableBuilder[A, Vector[A]] with VectorPointer[A]
A class to build instances of
Vector
.A class to build instances of
Vector
. This builder is reusable. - class VectorIterator[+A] extends AbstractIterator[A] with Iterator[A] with VectorPointer[A]
-
final
class
WrappedString extends AbstractSeq[Char] with IndexedSeq[Char] with StringLike[WrappedString]
This class serves as a wrapper augmenting
String
s with all the operations found in indexed sequences.This class serves as a wrapper augmenting
String
s with all the operations found in indexed sequences.The difference between this class and
StringOps
is that calling transformer methods such asfilter
andmap
will yield an object of typeWrappedString
rather than aString
.- Since
2.8
-
trait
MapProxy[A, +B] extends Map[A, B] with MapProxyLike[A, B, Map[A, B]]
This is a simple wrapper class for `scala.collection.immutable.Map`.
This is a simple wrapper class for `scala.collection.immutable.Map`.
It is most useful for assembling customized map abstractions dynamically using object composition and forwarding.
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) proxying is deprecated due to lack of use and compiler-level support
- Version
2.0, 31/12/2006
- Since
2.8
-
class
PagedSeq[T] extends AbstractSeq[T] with collection.IndexedSeq[T]
An implementation of lazily computed sequences, where elements are stored in "pages", i.e.
An implementation of lazily computed sequences, where elements are stored in "pages", i.e. arrays of fixed size.
A paged sequence is constructed from a function that produces more elements when asked. The producer function -
more
, is similar to the read method in java.io.Reader. Themore
function takes three parameters: an array of elements, a start index, and an end index. It should try to fill the array between start and end indices (excluding end index). It returns the number of elements produced, or -1 if end of logical input stream was reached before reading any element.- T
the type of the elements contained in this paged sequence, with an
ClassTag
context bound.
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.8) this class will be moved to the scala-parser-combinators module
- Since
2.7
-
trait
SetProxy[A] extends Set[A] with SetProxyLike[A, Set[A]]
This is a simple wrapper class for scala.collection.immutable.Set.
This is a simple wrapper class for scala.collection.immutable.Set.
It is most useful for assembling customized set abstractions dynamically using object composition and forwarding.
- A
type of the elements contained in this set proxy.
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) proxying is deprecated due to lack of use and compiler-level support.
- Since
2.8
-
class
Stack[+A] extends AbstractSeq[A] with LinearSeq[A] with GenericTraversableTemplate[A, Stack] with LinearSeqOptimized[A, Stack[A]] with Serializable
This class implements immutable stacks using a list-based data structure.
This class implements immutable stacks using a list-based data structure.
Note: This class exists only for historical reason and as an analogue of mutable stacks. Instead of an immutable stack you can just use a list.
- A
the type of the elements contained in this stack.
- Annotations
- @SerialVersionUID() @deprecated
- Deprecated
(Since version 2.11.0) Stack is an inelegant and potentially poorly-performing wrapper around List. Use List instead: stack push x becomes x :: list; stack.pop is list.tail.
- Version
1.0, 10/07/2003
- Since
1
- See also
"Scala's Collection Library overview" section on
Immutable stacks
for more information.
Value Members
-
object
BitSet extends BitSetFactory[BitSet] with Serializable
This object provides a set of operations to create
values.immutable.BitSet
-
object
HashMap extends ImmutableMapFactory[HashMap] with generic.BitOperations.Int with Serializable
This object provides a set of operations needed to create
values.immutable.HashMap
-
object
HashSet extends ImmutableSetFactory[HashSet] with Serializable
This object provides a set of operations needed to create
values.immutable.HashSet
-
object
IndexedSeq extends IndexedSeqFactory[IndexedSeq]
This object provides a set of operations to create
values.IndexedSeq
This object provides a set of operations to create
values. The current default implementation of aIndexedSeq
IndexedSeq
is aVector
. -
object
IntMap
A companion object for integer maps.
-
object
Iterable extends GenTraversableFactory[Iterable] with TraversableFactory[Iterable]
This object provides a set of operations to create
values.immutable.Iterable
This object provides a set of operations to create
values. The current default implementation of aimmutable.Iterable
immutable.Iterable
is aList
. -
object
LinearSeq extends SeqFactory[LinearSeq]
This object provides a set of operations to create
values.immutable.LinearSeq
This object provides a set of operations to create
values. The current default implementation of aimmutable.LinearSeq
immutable.LinearSeq
is aList
. -
object
List extends SeqFactory[List] with Serializable
This object provides a set of operations to create
values.List
-
object
ListMap extends ImmutableMapFactory[ListMap] with Serializable
This object provides a set of operations needed to create
ListMap
values.This object provides a set of operations needed to create
ListMap
values.Note that each element insertion takes O(n) time, which means that creating a list map with n elements will take O(n2) time. This makes the builder suitable only for a small number of elements.
- Since
1
- See also
"Scala's Collection Library overview" section on
List Maps
for more information.
-
object
ListSet extends ImmutableSetFactory[ListSet] with Serializable
This object provides a set of operations needed to create
ListSet
values.This object provides a set of operations needed to create
ListSet
values.Note that each element insertion takes O(n) time, which means that creating a list set with n elements will take O(n2) time. This makes the builder suitable only for a small number of elements.
- Since
1
-
object
LongMap
A companion object for long maps.
-
object
Map extends ImmutableMapFactory[Map]
This object provides a set of operations needed to create
values.immutable.Map
-
object
Nil extends List[Nothing] with Product with Serializable
The empty list.
The empty list.
- Annotations
- @SerialVersionUID()
- Version
1.0, 15/07/2003
- Since
2.8
-
object
NumericRange extends Serializable
A companion object for numeric ranges.
-
object
Queue extends SeqFactory[Queue] with Serializable
This object provides a set of operations to create
values.immutable.Queue
-
object
Range extends Serializable
A companion object for the
Range
class. -
object
Seq extends SeqFactory[Seq]
This object provides a set of operations to create
values.immutable.Seq
-
object
Set extends ImmutableSetFactory[Set]
This object provides a set of operations needed to create
values.immutable.Set
-
object
SortedMap extends ImmutableSortedMapFactory[SortedMap]
This object provides a set of operations needed to create sorted maps of type
immutable.SortedMap
. -
object
SortedSet extends ImmutableSortedSetFactory[SortedSet]
This object provides a set of operations needed to create sorted sets of type
.immutable.SortedSet
-
object
Stack extends SeqFactory[Stack] with Serializable
This object provides a set of operations to create
values.immutable.Stack
-
object
Stream extends SeqFactory[Stream] with Serializable
The object
Stream
provides helper functions to manipulate streams.The object
Stream
provides helper functions to manipulate streams.- Version
1.1 08/08/03
- Since
2.8
-
object
StringLike
A companion object for the
StringLike
containing some constants.A companion object for the
StringLike
containing some constants.- Since
2.8
-
object
Traversable extends GenTraversableFactory[Traversable] with TraversableFactory[Traversable]
This object provides a set of operations to create
values.immutable.Traversable
This object provides a set of operations to create
values. The current default implementation of aimmutable.Traversable
immutable.Traversable
is aList
. -
object
TreeMap extends ImmutableSortedMapFactory[TreeMap] with Serializable
This object provides a set of operations needed to create sorted maps of type
immutable.TreeMap
. -
object
TreeSet extends ImmutableSortedSetFactory[TreeSet] with Serializable
This object provides a set of operations needed to create sorted sets of type
.immutable.TreeSet
-
object
Vector extends IndexedSeqFactory[Vector] with Serializable
Companion object to the Vector class
-
object
WrappedString
A companion object for wrapped strings.
A companion object for wrapped strings.
- Since
2.8
Deprecated Value Members
-
object
PagedSeq
The
PagedSeq
object defines a lazy implementations of a random access sequence.The
PagedSeq
object defines a lazy implementations of a random access sequence.Provides utility methods that return instances of
PagedSeq[Char]
.fromIterator
andfromIterable
provide generalised instances ofPagedSeq
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.8) this object will be moved to the scala-parser-combinators module
- Since
2.7
This is the documentation for the Scala standard library.
Package structure
The scala package contains core types like
Int
,Float
,Array
orOption
which are accessible in all Scala compilation units without explicit qualification or imports.Notable packages include:
scala.collection
and its sub-packages contain Scala's collections frameworkscala.collection.immutable
- Immutable, sequential data-structures such asVector
,List
,Range
,HashMap
orHashSet
scala.collection.mutable
- Mutable, sequential data-structures such asArrayBuffer
,StringBuilder
,HashMap
orHashSet
scala.collection.concurrent
- Mutable, concurrent data-structures such asTrieMap
scala.collection.parallel.immutable
- Immutable, parallel data-structures such asParVector
,ParRange
,ParHashMap
orParHashSet
scala.collection.parallel.mutable
- Mutable, parallel data-structures such asParArray
,ParHashMap
,ParTrieMap
orParHashSet
scala.concurrent
- Primitives for concurrent programming such asFutures
andPromises
scala.io
- Input and output operationsscala.math
- Basic math functions and additional numeric types likeBigInt
andBigDecimal
scala.sys
- Interaction with other processes and the operating systemscala.util.matching
- Regular expressionsOther packages exist. See the complete list on the right.
Additional parts of the standard library are shipped as separate libraries. These include:
scala.reflect
- Scala's reflection API (scala-reflect.jar)scala.xml
- XML parsing, manipulation, and serialization (scala-xml.jar)scala.swing
- A convenient wrapper around Java's GUI framework called Swing (scala-swing.jar)scala.util.parsing
- Parser combinators (scala-parser-combinators.jar)Automatic imports
Identifiers in the scala package and the
scala.Predef
object are always in scope by default.Some of these identifiers are type aliases provided as shortcuts to commonly used classes. For example,
List
is an alias forscala.collection.immutable.List
.Other aliases refer to classes provided by the underlying platform. For example, on the JVM,
String
is an alias forjava.lang.String
.