scala.collection.immutable
Type members
Classlikes
Explicit instantiation of the Map
trait to reduce class file size in subclasses.
Explicit instantiation of the Map
trait to reduce class file size in subclasses.
Explicit instantiation of the Seq
trait to reduce class file size in subclasses.
Explicit instantiation of the Seq
trait to reduce class file size in subclasses.
Explicit instantiation of the Set
trait to reduce class file size in subclasses.
Explicit instantiation of the Set
trait to reduce class file size in subclasses.
An immutable array.
An immutable array.
Supports efficient indexed access and has a small memory footprint.
- Companion
- object
This object provides a set of operations to create ArraySeq
values.
This object provides a set of operations to create ArraySeq
values.
- Companion
- class
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 lower bound of memory footprint of a bitset is determined by the largest number stored in it.
- See also
"Scala's Collection Library overview" section on
Immutable BitSets
for more information.- Companion
- object
This object provides a set of operations to create immutable.BitSet
values.
This object provides a set of operations to create immutable.BitSet
values.
- Companion
- class
This class implements immutable maps using a Compressed Hash-Array Mapped Prefix-tree.
This class implements immutable maps using a Compressed Hash-Array Mapped Prefix-tree. See paper https://michael.steindorfer.name/publications/oopsla15.pdf for more details.
- Type Params
- K
the type of the keys contained in this hash set.
- V
the type of the values associated with the keys in this hash map.
- Companion
- object
This object provides a set of operations to create immutable.HashMap
values.
This object provides a set of operations to create immutable.HashMap
values.
- Companion
- class
This class implements immutable sets using a Compressed Hash-Array Mapped Prefix-tree.
This class implements immutable sets using a Compressed Hash-Array Mapped Prefix-tree. See paper https://michael.steindorfer.name/publications/oopsla15.pdf for more details.
- Type Params
- A
the type of the elements contained in this hash set.
- Companion
- object
This object provides a set of operations to create immutable.HashSet
values.
This object provides a set of operations to create immutable.HashSet
values.
- Companion
- class
Base trait for immutable indexed sequences that have efficient apply
and length
Base trait for immutable indexed sequences that have efficient apply
and length
- Companion
- object
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.
- Type Params
- T
type of the values associated with integer keys.
- Companion
- object
A trait for collections that are guaranteed immutable.
A trait for collections that are guaranteed immutable.
- Type Params
- A
the element type of the collection
- Companion
- object
This class implements an immutable linked list.
This class implements an immutable linked list. We call it "lazy" because it computes its elements only when they are needed.
Elements are memoized; that is, the value of each element is computed at most once.
Elements are computed in-order and are never skipped. In other words, accessing the tail causes the head to be computed first.
How lazy is a LazyList
? When you have a value of type LazyList
, you
don't know yet whether the list is empty or not. If you learn that it is non-empty,
then you also know that the head has been computed. But the tail is itself
a LazyList
, whose emptiness-or-not might remain undetermined.
A LazyList
may be infinite. For example, LazyList.from(0)
contains
all of the natural numbers 0, 1, 2, and so on. For infinite sequences,
some methods (such as count
, sum
, max
or min
) will not terminate.
Here is an example:
import scala.math.BigInt
object Main extends App {
val fibs: LazyList[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
To illustrate, let's add some output to the definition fibs
, so we
see what's going on.
import scala.math.BigInt
object Main extends App {
val fibs: LazyList[BigInt] =
BigInt(0) #:: BigInt(1) #::
fibs.zip(fibs.tail).map{ n =>
println(s"Adding ${n._1} and ${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
Note that the definition of fibs
uses val
not def
. The memoization of the
LazyList
requires us to have somewhere to store the information and a val
allows us to do that.
Further remarks about the semantics of LazyList
:
- Though the LazyList
changes as it is accessed, this does not
contradict its immutability. Once the values are memoized they do
not change. Values that have yet to be memoized still "exist", they
simply haven't been computed yet.
- One must be cautious of memoization; it can eat up memory if you're not
careful. That's because memoization of the LazyList
creates a structure much like
scala.collection.immutable.List. As long as something is holding on to
the head, the head holds on to the tail, and so on recursively.
If, on the other hand, there is nothing holding on to the head (e.g. if we used
def
to define the LazyList
) 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.
Here's another example. Let's start with the natural numbers and iterate 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 LazyList definition will be a val definition
val lazylist1: LazyList[Int] = {
def loop(v: Int): LazyList[Int] = v #:: loop(v + 1)
loop(0)
}
// Because lazylist1 is a val, everything that the iterator produces is held
// by virtue of the fact that the head of the LazyList is held in lazylist1
val it1 = lazylist1.iterator
loop("Iterator1: ", it1.next(), it1)
// We can redefine this LazyList such that all we have is the Iterator left
// and allow the LazyList to be garbage collected as required. Using a def
// to provide the LazyList ensures that no val is holding onto the head as
// is the case with lazylist1
def lazylist2: LazyList[Int] = {
def loop(v: Int): LazyList[Int] = v #:: loop(v + 1)
loop(0)
}
val it2 = lazylist2.iterator
loop("Iterator2: ", it2.next(), it2)
// And, of course, we don't actually need a LazyList at all for such a simple
// problem. There's no reason to use a LazyList 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)
- In the fibs
example earlier, the fact that tail
works at all is of interest.
fibs
has an initial (0, 1, LazyList(...))
, so tail
is deterministic.
If we defined fibs
such that only 0
were concretely known, then the act
of determining tail
would require the evaluation of tail
, so the
computation would be unable to progress, as in this code:
// 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: LazyList[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: LazyList[Int] = {
def loop(h: Int, n: Int): LazyList[Int] = h #:: loop(n, h + n)
loop(1, 1)
}
The head, the tail and whether the list is empty or not can be initially unknown.
Once any of those are evaluated, they are all known, though if the tail is
built with #::
or #:::
, it's content still isn't evaluated. Instead, evaluating
the tails content is deferred until the tails empty status, head or tail is
evaluated.
Delaying the evaluation of whether a LazyList is empty or not until it's needed
allows LazyList to not eagerly evaluate any elements on a call to filter
.
Only when it's further evaluated (which may be never!) any of the elements gets forced.
for example:
def tailWithSideEffect: LazyList[Nothing] = {
println("getting empty LazyList")
LazyList.empty
}
val emptyTail = tailWithSideEffect // prints "getting empty LazyList"
val suspended = 1 #:: tailWithSideEffect // doesn't print anything
val tail = suspended.tail // although the tail is evaluated, *still* nothing is yet printed
val filtered = tail.filter(_ => false) // still nothing is printed
filtered.isEmpty // prints "getting empty LazyList"
- Type Params
- A
the type of the elements contained in this lazy list.
- See also
"Scala's Collection Library overview" section on
LazyLists
for more information.- Companion
- object
This object provides a set of operations to create LazyList
values.
This object provides a set of operations to create LazyList
values.
- Companion
- class
Base trait for immutable linear sequences that have efficient head
and tail
Base trait for immutable linear sequences that have efficient head
and tail
- Companion
- object
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
and scala.::
that implement the abstract members isEmpty
,
head
and tail
.
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
.
Performance
Time: List
has O(1)
prepend and head/tail access. Most other operations are O(n)
on the number of elements in the list.
This includes the index-based lookup of elements, length
, append
and reverse
.
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
- See also
"Scala's Collection Library overview" section on
Lists
for more information.- 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.
- Example
// 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" :: Nil // Pattern match days match { case firstDay :: otherDays => println("The first day of the week is: " + firstDay) case Nil => println("There don't seem to be any week days.") }
- Companion
- object
This object provides a set of operations to create List
values.
This object provides a set of operations to create List
values.
- Companion
- class
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 they 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
and tail
are O(n), while last
and init
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 function ListMap.empty
.
- Type Params
- K
the type of the keys contained in this list map
- V
the type of the values associated with the keys
- Companion
- object
This object provides a set of operations to create ListMap values.
This object provides a set of operations 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.
- See also
"Scala's Collection Library overview" section on
List Maps
for more information.- Companion
- class
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 they 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
and tail
are O(n), while last
and
init
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 function ListSet.empty
.
- Type Params
- A
the type of the elements contained in this list set
- Companion
- object
This object provides a set of operations to create ListSet values.
This object provides a set of operations 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.
- Companion
- class
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.
- Type Params
- T
type of the values associated with the long keys.
- Companion
- object
Base type of immutable Maps
Base type of immutable Maps
- Companion
- object
This object provides a set of operations to create immutable.Map
values.
This object provides a set of operations to create immutable.Map
values.
- Companion
- class
Base trait of immutable Maps implementations
Base trait of immutable Maps implementations
NumericRange
is a more generic version of the
Range
class which works with arbitrary types.
NumericRange
is a more generic version of the
Range
class which works with arbitrary types.
It must be supplied with an Integral
implementation of the
range type.
Factories for likely types include Range.BigInt
, Range.Long
,
and Range.BigDecimal
. Range.Int
exists for completeness, but
the Int
-based scala.Range
should be more performant.
val r1 = Range(0, 100, 1)
val veryBig = Int.MaxValue.toLong + 1
val r2 = Range.Long(veryBig, veryBig + 100, 1)
assert(r1 sameElements r2.map(_ - veryBig))
- Companion
- object
A companion object for numeric ranges.
A companion object for numeric ranges.
- Companion
- class
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 of List
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 cost O(1)
, except in the case
where a pivot is required, in which case, a cost of O(n)
is incurred, where n
is the number of elements in the queue. When this happens,
n
remove operations with O(1)
cost are guaranteed. Removing an item is on average O(1)
.
- See also
"Scala's Collection Library overview" section on
Immutable Queues
for more information.- Companion
- object
This object provides a set of operations to create immutable.Queue
values.
This object provides a set of operations to create immutable.Queue
values.
- Companion
- class
The Range
class represents integer values in range
[start;end) with non-zero step value step
.
The Range
class represents integer values in range
[start;end) with non-zero step value step
.
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 over Int.MaxValue
length to be created, or
could be asked to index beyond Int.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.
- Value Params
- end
the end of the range. For exclusive ranges, e.g.
Range(0,3)
or(0 until 3)
, this is one step past the last one in the range. For inclusive ranges, e.g.Range.inclusive(0,3)
or(0 to 3)
, it may be in the range if it is not skipped by the step size. To find the last element inside a non-empty range, uselast
instead.- start
the start of this range.
- step
the step for the range.
- Companion
- object
- Companion
- object
This object provides a set of operations to create immutable.Seq
values.
This object provides a set of operations to create immutable.Seq
values.
- Companion
- class
A generic trait for ordered immutable maps.
A generic trait for ordered immutable maps. Concrete classes have to provide
functionality for the abstract methods in SeqMap
.
Note that when checking for equality SeqMap does not take into account ordering.
- Type Params
- K
the type of the keys contained in this linked map.
- V
the type of the values associated with the keys in this linked map.
- Companion
- object
Base trait for immutable set collections
Base trait for immutable set collections
- Companion
- object
This object provides a set of operations to create immutable.Set
values.
This object provides a set of operations to create immutable.Set
values.
- Companion
- class
An immutable map whose key-value pairs are sorted according to an scala.math.Ordering on the keys.
An immutable map whose key-value pairs are sorted according to an scala.math.Ordering on the keys.
Allows for range queries to be performed on its keys, and implementations must guarantee that traversal happens in sorted order, according to the map's scala.math.Ordering.
- Type Params
- K
the type of the keys contained in this tree map.
- V
the type of the values associated with the keys.
- Example
import scala.collection.immutable.SortedMap // Make a SortedMap via the companion object factory val weekdays = SortedMap( 2 -> "Monday", 3 -> "Tuesday", 4 -> "Wednesday", 5 -> "Thursday", 6 -> "Friday" ) // TreeMap(2 -> Monday, 3 -> Tuesday, 4 -> Wednesday, 5 -> Thursday, 6 -> Friday) val days = weekdays ++ List(1 -> "Sunday", 7 -> "Saturday") // TreeMap(1 -> Sunday, 2 -> Monday, 3 -> Tuesday, 4 -> Wednesday, 5 -> Thursday, 6 -> Friday, 7 -> Saturday) val day3 = days.get(3) // Some("Tuesday") val rangeOfDays = days.range(2, 5) // TreeMap(2 -> Monday, 3 -> Tuesday, 4 -> Wednesday) val daysUntil2 = days.rangeUntil(2) // TreeMap(1 -> Sunday) val daysTo2 = days.rangeTo(2) // TreeMap(1 -> Sunday, 2 -> Monday) val daysAfter5 = days.rangeFrom(5) // TreeMap(5 -> Thursday, 6 -> Friday, 7 -> Saturday)
- Companion
- object
Base trait for sorted sets
Base trait for sorted sets
- Companion
- object
This object provides a set of operations to create immutable.SortedSet
values.
This object provides a set of operations to create immutable.SortedSet
values.
- Companion
- class
Trait that overrides operations to take advantage of strict builders.
Trait that overrides operations to take advantage of strict builders.
An immutable SortedMap whose values are stored in a red-black tree.
An immutable SortedMap whose values are stored in a red-black tree.
This class is optimal when range queries will be performed, or when traversal in order of an ordering is desired. If you only need key lookups, and don't care in which order key-values are traversed in, consider using * scala.collection.immutable.HashMap, which will generally have better performance. If you need insertion order, consider a * scala.collection.immutable.SeqMap, which does not need to have an ordering supplied.
- Type Params
- K
the type of the keys contained in this tree map.
- V
the type of the values associated with the keys.
- Value Params
- ordering
the implicit ordering used to compare objects of type
A
.
- See also
"Scala's Collection Library overview" section on
Red-Black Trees
for more information.- Example
import scala.collection.immutable.TreeMap // Make a TreeMap via the companion object factory val weekdays = TreeMap( 2 -> "Monday", 3 -> "Tuesday", 4 -> "Wednesday", 5 -> "Thursday", 6 -> "Friday" ) // TreeMap(2 -> Monday, 3 -> Tuesday, 4 -> Wednesday, 5 -> Thursday, 6 -> Friday) val days = weekdays ++ List(1 -> "Sunday", 7 -> "Saturday") // TreeMap(1 -> Sunday, 2 -> Monday, 3 -> Tuesday, 4 -> Wednesday, 5 -> Thursday, 6 -> Friday, 7 -> Saturday) val day3 = days.get(3) // Some("Tuesday") val rangeOfDays = days.range(2, 5) // TreeMap(2 -> Monday, 3 -> Tuesday, 4 -> Wednesday) val daysUntil2 = days.rangeUntil(2) // TreeMap(1 -> Sunday) val daysTo2 = days.rangeTo(2) // TreeMap(1 -> Sunday, 2 -> Monday) val daysAfter5 = days.rangeFrom(5) // TreeMap(5 -> Thursday, 6 -> Friday, 7 -> Saturday)
- Companion
- object
This object provides a set of operations to create immutable.TreeMap values.
This object provides a set of operations to create immutable.TreeMap values.
- Companion
- class
This class implements an immutable map that preserves order using a hash map for the key to value mapping to provide efficient lookup, and a tree for the ordering of the keys to provide efficient insertion/modification order traversal and destructuring.
This class implements an immutable map that preserves order using a hash map for the key to value mapping to provide efficient lookup, and a tree for the ordering of the keys to provide efficient insertion/modification order traversal and destructuring.
By default insertion order (TreeSeqMap.OrderBy.Insertion
)
is used, but modification order (TreeSeqMap.OrderBy.Modification
)
can be used instead if so specified at creation.
The orderingBy(orderBy: TreeSeqMap.OrderBy): TreeSeqMap[K, V]
method
can be used to switch to the specified ordering for the returned map.
A key can be manually refreshed (i.e. placed at the end) via the
refresh(key: K): TreeSeqMap[K, V]
method (regardless of the ordering in
use).
Internally, an ordinal counter is increased for each insertion/modification and then the current ordinal is used as key in the tree map. After 232 insertions/modifications the entire map is copied (thus resetting the ordinal counter).
- Type Params
- K
the type of the keys contained in this map.
- V
the type of the values associated with the keys in this map.
- Companion
- object
This class implements immutable sorted sets using a tree.
This class implements immutable sorted sets using a tree.
- Type Params
- A
the type of the elements contained in this tree set
- Value Params
- ordering
the implicit ordering used to compare objects of type
A
- See also
"Scala's Collection Library overview" section on
Red-Black Trees
for more information.- Companion
- object
This object provides a set of operations to create immutable.TreeSet
values.
This object provides a set of operations to create immutable.TreeSet
values.
- Companion
- class
This object provides a set of operations to create Vector
values.
This object provides a set of operations to create Vector
values.
- Companion
- class
Vector is a general-purpose, immutable data structure.
Vector is a general-purpose, immutable data structure. It provides random access and updates in O(log n) time, as well as very fast append/prepend/tail/init (amortized O(1), worst case O(log n)). 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.
Vectors are implemented by radix-balanced finger trees of width 32. There is a separate subclass for each level (0 to 6, with 0 being the empty vector and 6 a tree with a maximum width of 64 at the top level).
Tree balancing:
- Only the first dimension of an array may have a size < WIDTH
- In a data
(central) array the first dimension may be up to WIDTH-2 long, in prefix1
and suffix1
up
to WIDTH, and in other prefix
and suffix
arrays up to WIDTH-1
- prefix1
and suffix1
are never empty
- Balancing does not cross the main data array (i.e. prepending never touches the suffix and appending never touches
the prefix). The level is increased/decreased when the affected side plus main data is already full/empty
- All arrays are left-aligned and truncated
In addition to the data slices (prefix1
, prefix2
, ..., dataN
, ..., suffix2
, suffix1
) we store a running
count of elements after each prefix for more efficient indexing without having to dereference all prefix arrays.
- Companion
- object
This class implements immutable maps using a vector/map-based data structure, which preserves insertion order.
This class implements immutable maps using a vector/map-based data structure, which preserves insertion order.
Unlike ListMap
, VectorMap
has amortized effectively constant lookup at the expense
of using extra memory and generally lower performance for other operations
- Type Params
- K
the type of the keys contained in this vector map.
- V
the type of the values associated with the keys in this vector map.
- Companion
- object
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 as filter
and map
will yield an object of type WrappedString
rather than a String
.
- Value Params
- self
a string contained within this wrapped string
- Companion
- object
A companion object for wrapped strings.
A companion object for wrapped strings.
- Companion
- class
Deprecated classlikes
- Companion
- object
- Deprecated
- Companion
- class
- Deprecated