scala

package scala

Core Scala types. They are always available without an explicit import.

Type members

Classlikes

object #::
sealed abstract class *:[+H, +T <: Tuple] extends NonEmptyTuple
Companion:
object
Source:
Tuple.scala
object *:
Companion:
class
Source:
Tuple.scala
sealed abstract class <:<[-From, +To] extends From => To with Serializable

An instance of A <:< B witnesses that A is a subtype of B.

An instance of A <:< B witnesses that A is a subtype of B. Requiring an implicit argument of the type A <:< B encodes the generalized constraint A <: B.

To constrain any abstract type T that's in scope in a method's argument list (not just the method's own type parameters) simply add an implicit argument of type T <:< U, where U is the required upper bound; or for lower-bounds, use: L <:< T, where L is the required lower bound.

In case of any confusion over which method goes in what direction, all the "Co" methods (including apply) go from left to right in the type ("with" the type), and all the "Contra" methods go from right to left ("against" the type). E.g., apply turns a From into a To, and substituteContra replaces the Tos in a type with Froms.

In part contributed by Jason Zaugg.

Type parameters:
From

a type which is proved a subtype of To

To

a type which is proved a supertype of From

See also:

=:= for expressing equality constraints

Example:

scala.Option#flatten

sealed trait Option[+A] {
  // def flatten[B, A <: Option[B]]: Option[B] = ...
  // won't work, since the A in flatten shadows the class-scoped A.
  def flatten[B](implicit ev: A <:< Option[B]): Option[B]
    = if(isEmpty) None else ev(get)
  // Because (A <:< Option[B]) <: (A => Option[B]), ev can be called to turn the
  // A from get into an Option[B], and because ev is implicit, that call can be
  // left out and inserted automatically.
}
Companion:
object
Source:
typeConstraints.scala
object <:<
sealed abstract class =:=[From, To] extends From <:< To with Serializable

An instance of A =:= B witnesses that the types A and B are equal.

An instance of A =:= B witnesses that the types A and B are equal. It also acts as a A <:< B, but not a B <:< A (directly) due to restrictions on subclassing.

In case of any confusion over which method goes in what direction, all the "Co" methods (including apply) go from left to right in the type ("with" the type), and all the "Contra" methods go from right to left ("against" the type). E.g., apply turns a From into a To, and substituteContra replaces the Tos in a type with Froms.

Type parameters:
From

a type which is proved equal to To

To

a type which is proved equal to From

See also:

<:< for expressing subtyping constraints

Example:

An in-place variant of scala.collection.mutable.ArrayBuffer#transpose

implicit class BufOps[A](private val buf: ArrayBuffer[A]) extends AnyVal {
  def inPlaceTranspose[E]()(implicit ev: A =:= ArrayBuffer[E]) = ???
  // Because ArrayBuffer is invariant, we can't make do with just a A <:< ArrayBuffer[E]
  // Getting buffers *out* from buf would work, but adding them back *in* wouldn't.
}
Source:
typeConstraints.scala
abstract open class Any

Class Any is the root of the Scala class hierarchy.

Class Any is the root of the Scala class hierarchy. Every class in a Scala execution environment inherits directly or indirectly from this class.

Starting with Scala 2.10 it is possible to directly extend Any using universal traits. A universal trait is a trait that extends Any, only has defs as members, and does no initialization.

The main use case for universal traits is to allow basic inheritance of methods for value classes. For example,

trait Printable extends Any {
  def print(): Unit = println(this)
}
class Wrapper(val underlying: Int) extends AnyVal with Printable

val w = new Wrapper(3)
w.print()

See the Value Classes and Universal Traits for more details on the interplay of universal traits and value classes.

final abstract class AnyKind

The super-type of all types.

class AnyRef

Class AnyRef is the root class of all reference types.

Class AnyRef is the root class of all reference types. All types except the value types descend from this class.

abstract open class AnyVal

AnyVal is the root class of all value types, which describe values not implemented as objects in the underlying host system.

AnyVal is the root class of all value types, which describe values not implemented as objects in the underlying host system. Value classes are specified in Scala Language Specification, section 12.2.

The standard implementation includes nine AnyVal subtypes:

scala.Double, scala.Float, scala.Long, scala.Int, scala.Char, scala.Short, and scala.Byte are the numeric value types.

scala.Unit and scala.Boolean are the non-numeric value types.

Other groupings:

Prior to Scala 2.10, AnyVal was a sealed trait. Beginning with Scala 2.10, however, it is possible to define a subclass of AnyVal called a user-defined value class which is treated specially by the compiler. Properly-defined user value classes provide a way to improve performance on user-defined types by avoiding object allocation at runtime, and by replacing virtual method invocations with static method invocations.

User-defined value classes which avoid object allocation...

  • must have a single val parameter that is the underlying runtime representation.

  • can define defs, but no vals, vars, or nested traitss, classes or objects.

  • typically extend no other trait apart from AnyVal.

  • cannot be used in type tests or pattern matching.

  • may not override equals or hashCode methods.

A minimal example:

class Wrapper(val underlying: Int) extends AnyVal {
  def foo: Wrapper = new Wrapper(underlying * 19)
}

It's important to note that user-defined value classes are limited, and in some circumstances, still must allocate a value class instance at runtime. These limitations and circumstances are explained in greater detail in the Value Classes and Universal Traits.

trait App extends DelayedInit

The App trait can be used to quickly turn objects into executable programs.

The App trait can be used to quickly turn objects into executable programs. Here is an example:

object Main extends App {
  Console.println("Hello World: " + (args mkString ", "))
}

No explicit main method is needed. Instead, the whole class body becomes the “main method”.

args returns the current command line arguments as an array.

Caveats

It should be noted that this trait is implemented using the DelayedInit functionality, which means that fields of the object will not have been initialized before the main method has been executed.

Future versions of this trait will no longer extend DelayedInit.

Source:
App.scala
object Array

Utility methods for operating on arrays.

Utility methods for operating on arrays. For example:

val a = Array(1, 2)
val b = Array.ofDim[Int](2)
val c = Array.concat(a, b)

where the array objects a, b and c have respectively the values Array(1, 2), Array(0, 0) and Array(1, 2, 0, 0).

Companion:
class
Source:
Array.scala
final class Array[T](_length: Int) extends Serializable with Cloneable

Arrays are mutable, indexed collections of values.

Arrays are mutable, indexed collections of values. Array[T] is Scala's representation for Java's T[].

val numbers = Array(1, 2, 3, 4)
val first = numbers(0) // read the first element
numbers(3) = 100 // replace the 4th array element with 100
val biggerNumbers = numbers.map(_ * 2) // multiply all numbers by two

Arrays make use of two common pieces of Scala syntactic sugar, shown on lines 2 and 3 of the above example code. Line 2 is translated into a call to apply(Int), while line 3 is translated into a call to update(Int, T).

Two implicit conversions exist in scala.Predef that are frequently applied to arrays: a conversion to scala.collection.ArrayOps (shown on line 4 of the example above) and a conversion to scala.collection.mutable.ArraySeq (a subtype of scala.collection.Seq). Both types make available many of the standard operations found in the Scala collections API. The conversion to ArrayOps is temporary, as all operations defined on ArrayOps return an Array, while the conversion to ArraySeq is permanent as all operations return a ArraySeq.

The conversion to ArrayOps takes priority over the conversion to ArraySeq. For instance, consider the following code:

val arr = Array(1, 2, 3)
val arrReversed = arr.reverse
val seqReversed : collection.Seq[Int] = arr.reverse

Value arrReversed will be of type Array[Int], with an implicit conversion to ArrayOps occurring to perform the reverse operation. The value of seqReversed, on the other hand, will be computed by converting to ArraySeq first and invoking the variant of reverse that returns another ArraySeq.

See also:

Scala Language Specification, for in-depth information on the transformations the Scala compiler makes on Arrays (Sections 6.6 and 6.15 respectively.)

"Scala 2.8 Arrays" the Scala Improvement Document detailing arrays since Scala 2.8.

"The Scala 2.8 Collections' API" section on Array by Martin Odersky for more information.

Companion:
object
Source:
Array.scala
final abstract class Boolean extends AnyVal

Boolean (equivalent to Java's boolean primitive type) is a subtype of scala.AnyVal.

Boolean (equivalent to Java's boolean primitive type) is a subtype of scala.AnyVal. Instances of Boolean are not represented by an object in the underlying runtime system.

There is an implicit conversion from scala.Boolean => scala.runtime.RichBoolean which provides useful non-primitive operations.

Companion:
object
Source:
Boolean.scala
object Boolean
Companion:
class
Source:
Boolean.scala
final abstract class Byte extends AnyVal

Byte, a 8-bit signed integer (equivalent to Java's byte primitive type) is a subtype of scala.AnyVal.

Byte, a 8-bit signed integer (equivalent to Java's byte primitive type) is a subtype of scala.AnyVal. Instances of Byte are not represented by an object in the underlying runtime system.

There is an implicit conversion from scala.Byte => scala.runtime.RichByte which provides useful non-primitive operations.

Companion:
object
Source:
Byte.scala
object Byte
Companion:
class
Source:
Byte.scala
sealed trait CanEqual[-L, -R]

A marker trait indicating that values of type L can be compared to values of type R.

A marker trait indicating that values of type L can be compared to values of type R.

Companion:
object
Source:
CanEqual.scala
object CanEqual

Companion object containing a few universally known CanEqual instances. CanEqual instances involving primitive types or the Null type are handled directly in the compiler (see Implicits.synthesizedCanEqual), so they are not included here.

Companion object containing a few universally known CanEqual instances. CanEqual instances involving primitive types or the Null type are handled directly in the compiler (see Implicits.synthesizedCanEqual), so they are not included here.

Companion:
class
Source:
CanEqual.scala
erased class CanThrow[-E <: Exception]

A capability class that allows to throw exception E. When used with the experimental.saferExceptions feature, a throw Ex() expression will require a given of class CanThrow[Ex] to be available.

A capability class that allows to throw exception E. When used with the experimental.saferExceptions feature, a throw Ex() expression will require a given of class CanThrow[Ex] to be available.

Source:
CanThrow.scala
final abstract class Char extends AnyVal

Char, a 16-bit unsigned integer (equivalent to Java's char primitive type) is a subtype of scala.AnyVal.

Char, a 16-bit unsigned integer (equivalent to Java's char primitive type) is a subtype of scala.AnyVal. Instances of Char are not represented by an object in the underlying runtime system.

There is an implicit conversion from scala.Char => scala.runtime.RichChar which provides useful non-primitive operations.

Companion:
object
Source:
Char.scala
object Char
Companion:
class
Source:
Char.scala
object Console extends AnsiColor

Implements functionality for printing Scala values on the terminal.

Implements functionality for printing Scala values on the terminal. For reading values use StdIn. Also defines constants for marking up text on ANSI terminals.

Console Output

Use the print methods to output text.

scala> Console.printf(
  "Today the outside temperature is a balmy %.1f°C. %<.1f°C beats the previous record of %.1f°C.\n",
  -137.0,
  -135.05)
Today the outside temperature is a balmy -137.0°C. -137.0°C beats the previous record of -135.1°C.

ANSI escape codes

Use the ANSI escape codes for colorizing console output either to STDOUT or STDERR.

import Console.{GREEN, RED, RESET, YELLOW_B, UNDERLINED}

object PrimeTest {

  def isPrime(): Unit = {

    val candidate = io.StdIn.readInt().ensuring(_ > 1)

    val prime = (2 to candidate - 1).forall(candidate % _ != 0)

    if (prime)
      Console.println(s"${RESET}${GREEN}yes${RESET}")
    else
      Console.err.println(s"${RESET}${YELLOW_B}${RED}${UNDERLINED}NO!${RESET}")
  }

  def main(args: Array[String]): Unit = isPrime()

}

$ scala PrimeTest
1234567891
yes
$ scala PrimeTest
56474
NO!

IO redefinition

Use IO redefinition to temporarily swap in a different set of input and/or output streams. In this example the stream based method above is wrapped into a function.

import java.io.{ByteArrayOutputStream, StringReader}

object FunctionalPrimeTest {

  def isPrime(candidate: Int): Boolean = {

    val input = new StringReader(s"$candidate\n")
    val outCapture = new ByteArrayOutputStream
    val errCapture = new ByteArrayOutputStream

    Console.withIn(input) {
      Console.withOut(outCapture) {
        Console.withErr(errCapture) {
          PrimeTest.isPrime()
        }
      }
    }

    if (outCapture.toByteArray.nonEmpty) // "yes"
      true
    else if (errCapture.toByteArray.nonEmpty) // "NO!"
      false
    else throw new IllegalArgumentException(candidate.toString)
  }

  def main(args: Array[String]): Unit = {
    val primes = (2 to 50) filter (isPrime)
    println(s"First primes: $primes")
  }

}

$ scala FunctionalPrimeTest
First primes: Vector(2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47)

Source:
Console.scala
abstract class Conversion[-T, +U] extends T => U

A class for implicit values that can serve as implicit conversions. The implicit resolution algorithm will act as if there existed the additional implicit definition:

A class for implicit values that can serve as implicit conversions. The implicit resolution algorithm will act as if there existed the additional implicit definition:

def $implicitConversion[T, U](x: T)(c: Conversion[T, U]): U = c(x)

However, the presence of this definition would slow down implicit search since its outermost type matches any pair of types. Therefore, implicit search contains a special case in Implicits#discardForView which emulates the conversion in a more efficient way.

Note that this is a SAM class - function literals are automatically converted to the Conversion values.

Also note that in bootstrapped dotty, Predef.<:< should inherit from Conversion. This would cut the number of special cases in discardForView from two to one.

The Conversion class can also be used to convert explicitly, using the convert extension method.

Source:
Conversion.scala
final abstract class Double extends AnyVal

Double, a 64-bit IEEE-754 floating point number (equivalent to Java's double primitive type) is a subtype of scala.AnyVal.

Double, a 64-bit IEEE-754 floating point number (equivalent to Java's double primitive type) is a subtype of scala.AnyVal. Instances of Double are not represented by an object in the underlying runtime system.

There is an implicit conversion from scala.Double => scala.runtime.RichDouble which provides useful non-primitive operations.

Companion:
object
Source:
Double.scala
object Double
Companion:
class
Source:
Double.scala
final class DummyImplicit

A type for which there is always an implicit value.

A type for which there is always an implicit value.

Companion:
object
Source:
DummyImplicit.scala
trait Dynamic

A marker trait that enables dynamic invocations.

A marker trait that enables dynamic invocations. Instances x of this trait allow method invocations x.meth(args) for arbitrary method names meth and argument lists args as well as field accesses x.field for arbitrary field names field.

If a call is not natively supported by x (i.e. if type checking fails), it is rewritten according to the following rules:

foo.method("blah")      ~~> foo.applyDynamic("method")("blah")
foo.method(x = "blah")  ~~> foo.applyDynamicNamed("method")(("x", "blah"))
foo.method(x = 1, 2)    ~~> foo.applyDynamicNamed("method")(("x", 1), ("", 2))
foo.field           ~~> foo.selectDynamic("field")
foo.varia = 10      ~~> foo.updateDynamic("varia")(10)
foo.arr(10) = 13    ~~> foo.selectDynamic("arr").update(10, 13)
foo.arr(10)         ~~> foo.applyDynamic("arr")(10)

As of Scala 2.10, defining direct or indirect subclasses of this trait is only possible if the language feature dynamics is enabled.

Source:
Dynamic.scala
case object EmptyTuple extends Tuple

A tuple of 0 elements.

A tuple of 0 elements.

Source:
Tuple.scala
abstract class Enumeration(initial: Int) extends Serializable

Defines a finite set of values specific to the enumeration.

Defines a finite set of values specific to the enumeration. Typically these values enumerate all possible forms something can take and provide a lightweight alternative to case classes.

Each call to a Value method adds a new unique value to the enumeration. To be accessible, these values are usually defined as val members of the enumeration.

All values in an enumeration share a common, unique type defined as the Value type member of the enumeration (Value selected on the stable identifier path of the enumeration instance).

Values SHOULD NOT be added to an enumeration after its construction; doing so makes the enumeration thread-unsafe. If values are added to an enumeration from multiple threads (in a non-synchronized fashion) after construction, the behavior of the enumeration is undefined.

Value parameters:
initial

The initial value from which to count the integers that identifies values at run-time.

Example:

// Define a new enumeration with a type alias and work with the full set of enumerated values
object WeekDay extends Enumeration {
 type WeekDay = Value
 val Mon, Tue, Wed, Thu, Fri, Sat, Sun = Value
}
import WeekDay._
def isWorkingDay(d: WeekDay) = ! (d == Sat || d == Sun)
WeekDay.values filter isWorkingDay foreach println
// output:
// Mon
// Tue
// Wed
// Thu
// Fri

// Example of adding attributes to an enumeration by extending the Enumeration.Val class
object Planet extends Enumeration {
 protected case class PlanetVal(mass: Double, radius: Double) extends super.Val {
   def surfaceGravity: Double = Planet.G * mass / (radius * radius)
   def surfaceWeight(otherMass: Double): Double = otherMass * surfaceGravity
 }
 import scala.language.implicitConversions
 implicit def valueToPlanetVal(x: Value): PlanetVal = x.asInstanceOf[PlanetVal]
 val G: Double = 6.67300E-11
 val Mercury = PlanetVal(3.303e+23, 2.4397e6)
 val Venus   = PlanetVal(4.869e+24, 6.0518e6)
 val Earth   = PlanetVal(5.976e+24, 6.37814e6)
 val Mars    = PlanetVal(6.421e+23, 3.3972e6)
 val Jupiter = PlanetVal(1.9e+27, 7.1492e7)
 val Saturn  = PlanetVal(5.688e+26, 6.0268e7)
 val Uranus  = PlanetVal(8.686e+25, 2.5559e7)
 val Neptune = PlanetVal(1.024e+26, 2.4746e7)
}
println(Planet.values.filter(_.radius > 7.0e6))
// output:
// Planet.ValueSet(Jupiter, Saturn, Uranus, Neptune)
Source:
Enumeration.scala
trait Equals

An interface containing operations for equality.

An interface containing operations for equality. The only method not already present in class AnyRef is canEqual.

Source:
Equals.scala
final abstract class Float extends AnyVal

Float, a 32-bit IEEE-754 floating point number (equivalent to Java's float primitive type) is a subtype of scala.AnyVal.

Float, a 32-bit IEEE-754 floating point number (equivalent to Java's float primitive type) is a subtype of scala.AnyVal. Instances of Float are not represented by an object in the underlying runtime system.

There is an implicit conversion from scala.Float => scala.runtime.RichFloat which provides useful non-primitive operations.

Companion:
object
Source:
Float.scala
object Float
Companion:
class
Source:
Float.scala
object Function

A module defining utility methods for higher-order functional programming.

A module defining utility methods for higher-order functional programming.

Source:
Function.scala
trait Function0[+R] extends AnyRef

A function of 0 parameters.

A function of 0 parameters.

In the following example, the definition of javaVersion is a shorthand for the anonymous class definition anonfun0:

object Main extends App {
  val javaVersion = () => sys.props("java.version")

  val anonfun0 = new Function0[String] {
    def apply(): String = sys.props("java.version")
  }
  assert(javaVersion() == anonfun0())
}
Source:
Function0.scala
object Function1
Companion:
class
Source:
Function1.scala
trait Function1[-T1, +R] extends AnyRef

A function of 1 parameter.

A function of 1 parameter.

In the following example, the definition of succ is a shorthand for the anonymous class definition anonfun1:

object Main extends App {
  val succ = (x: Int) => x + 1
  val anonfun1 = new Function1[Int, Int] {
    def apply(x: Int): Int = x + 1
  }
  assert(succ(0) == anonfun1(0))
}

Note that the difference between Function1 and scala.PartialFunction is that the latter can specify inputs which it will not handle.

Companion:
object
Source:
Function1.scala
trait Function10[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, +R] extends AnyRef

A function of 10 parameters.

A function of 10 parameters.

Source:
Function10.scala
trait Function11[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, -T11, +R] extends AnyRef

A function of 11 parameters.

A function of 11 parameters.

Source:
Function11.scala
trait Function12[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, -T11, -T12, +R] extends AnyRef

A function of 12 parameters.

A function of 12 parameters.

Source:
Function12.scala
trait Function13[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, -T11, -T12, -T13, +R] extends AnyRef

A function of 13 parameters.

A function of 13 parameters.

Source:
Function13.scala
trait Function14[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, -T11, -T12, -T13, -T14, +R] extends AnyRef

A function of 14 parameters.

A function of 14 parameters.

Source:
Function14.scala
trait Function15[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, -T11, -T12, -T13, -T14, -T15, +R] extends AnyRef

A function of 15 parameters.

A function of 15 parameters.

Source:
Function15.scala
trait Function16[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, -T11, -T12, -T13, -T14, -T15, -T16, +R] extends AnyRef

A function of 16 parameters.

A function of 16 parameters.

Source:
Function16.scala
trait Function17[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, -T11, -T12, -T13, -T14, -T15, -T16, -T17, +R] extends AnyRef

A function of 17 parameters.

A function of 17 parameters.

Source:
Function17.scala
trait Function18[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, -T11, -T12, -T13, -T14, -T15, -T16, -T17, -T18, +R] extends AnyRef

A function of 18 parameters.

A function of 18 parameters.

Source:
Function18.scala
trait Function19[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, -T11, -T12, -T13, -T14, -T15, -T16, -T17, -T18, -T19, +R] extends AnyRef

A function of 19 parameters.

A function of 19 parameters.

Source:
Function19.scala
trait Function2[-T1, -T2, +R] extends AnyRef

A function of 2 parameters.

A function of 2 parameters.

In the following example, the definition of max is a shorthand for the anonymous class definition anonfun2:

object Main extends App {
  val max = (x: Int, y: Int) => if (x < y) y else x

  val anonfun2 = new Function2[Int, Int, Int] {
    def apply(x: Int, y: Int): Int = if (x < y) y else x
  }
  assert(max(0, 1) == anonfun2(0, 1))
}
Source:
Function2.scala
trait Function20[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, -T11, -T12, -T13, -T14, -T15, -T16, -T17, -T18, -T19, -T20, +R] extends AnyRef

A function of 20 parameters.

A function of 20 parameters.

Source:
Function20.scala
trait Function21[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, -T11, -T12, -T13, -T14, -T15, -T16, -T17, -T18, -T19, -T20, -T21, +R] extends AnyRef

A function of 21 parameters.

A function of 21 parameters.

Source:
Function21.scala
trait Function22[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, -T10, -T11, -T12, -T13, -T14, -T15, -T16, -T17, -T18, -T19, -T20, -T21, -T22, +R] extends AnyRef

A function of 22 parameters.

A function of 22 parameters.

Source:
Function22.scala
trait Function3[-T1, -T2, -T3, +R] extends AnyRef

A function of 3 parameters.

A function of 3 parameters.

Source:
Function3.scala
trait Function4[-T1, -T2, -T3, -T4, +R] extends AnyRef

A function of 4 parameters.

A function of 4 parameters.

Source:
Function4.scala
trait Function5[-T1, -T2, -T3, -T4, -T5, +R] extends AnyRef

A function of 5 parameters.

A function of 5 parameters.

Source:
Function5.scala
trait Function6[-T1, -T2, -T3, -T4, -T5, -T6, +R] extends AnyRef

A function of 6 parameters.

A function of 6 parameters.

Source:
Function6.scala
trait Function7[-T1, -T2, -T3, -T4, -T5, -T6, -T7, +R] extends AnyRef

A function of 7 parameters.

A function of 7 parameters.

Source:
Function7.scala
trait Function8[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, +R] extends AnyRef

A function of 8 parameters.

A function of 8 parameters.

Source:
Function8.scala
trait Function9[-T1, -T2, -T3, -T4, -T5, -T6, -T7, -T8, -T9, +R] extends AnyRef

A function of 9 parameters.

A function of 9 parameters.

Source:
Function9.scala
object IArray

An immutable array. An IArray[T] has the same representation as an Array[T], but it cannot be updated. Unlike regular arrays, immutable arrays are covariant.

An immutable array. An IArray[T] has the same representation as an Array[T], but it cannot be updated. Unlike regular arrays, immutable arrays are covariant.

Source:
IArray.scala
final abstract class Int extends AnyVal

Int, a 32-bit signed integer (equivalent to Java's int primitive type) is a subtype of scala.AnyVal.

Int, a 32-bit signed integer (equivalent to Java's int primitive type) is a subtype of scala.AnyVal. Instances of Int are not represented by an object in the underlying runtime system.

There is an implicit conversion from scala.Int => scala.runtime.RichInt which provides useful non-primitive operations.

Companion:
object
Source:
Int.scala
object Int
Companion:
class
Source:
Int.scala
final abstract class Long extends AnyVal

Long, a 64-bit signed integer (equivalent to Java's long primitive type) is a subtype of scala.AnyVal.

Long, a 64-bit signed integer (equivalent to Java's long primitive type) is a subtype of scala.AnyVal. Instances of Long are not represented by an object in the underlying runtime system.

There is an implicit conversion from scala.Long => scala.runtime.RichLong which provides useful non-primitive operations.

Companion:
object
Source:
Long.scala
object Long
Companion:
class
Source:
Long.scala
final class MatchError(obj: Any) extends RuntimeException

This class implements errors which are thrown whenever an object doesn't match any pattern of a pattern matching expression.

This class implements errors which are thrown whenever an object doesn't match any pattern of a pattern matching expression.

Source:
MatchError.scala
open class Matchable

The base trait of types that can be safely pattern matched against.

The base trait of types that can be safely pattern matched against.

See https://docs.scala-lang.org/scala3/reference/other-new-features/matchable.html.

sealed trait NonEmptyTuple extends Tuple

Tuple of arbitrary non-zero arity

Tuple of arbitrary non-zero arity

Source:
Tuple.scala
case object None extends Option[Nothing]

This case object represents non-existent values.

This case object represents non-existent values.

Source:
Option.scala
final class NotImplementedError(msg: String) extends Error

Throwing this exception can be a temporary replacement for a method body that remains to be implemented.

Throwing this exception can be a temporary replacement for a method body that remains to be implemented. For instance, the exception is thrown by Predef.???.

Source:
NotImplementedError.scala
final abstract open class Nothing

Nothing is - together with scala.Null - at the bottom of Scala's type hierarchy.

Nothing is - together with scala.Null - at the bottom of Scala's type hierarchy.

Nothing is a subtype of every other type (including scala.Null); there exist no instances of this type. Although type Nothing is uninhabited, it is nevertheless useful in several ways. For instance, the Scala library defines a value scala.collection.immutable.Nil of type List[Nothing]. Because lists are covariant in Scala, this makes scala.collection.immutable.Nil an instance of List[T], for any element of type T.

Another usage for Nothing is the return type for methods which never return normally. One example is method error in scala.sys, which always throws an exception.

final abstract open class Null

Null is - together with scala.Nothing - at the bottom of the Scala type hierarchy.

Null is - together with scala.Nothing - at the bottom of the Scala type hierarchy.

Null is the type of the null literal. It is a subtype of every type except those of value classes. Value classes are subclasses of AnyVal, which includes primitive types such as Int, Boolean, and user-defined value classes.

Since Null is not a subtype of value types, null is not a member of any such type. For instance, it is not possible to assign null to a variable of type scala.Int.

object Option
Companion:
class
Source:
Option.scala
sealed abstract class Option[+A] extends IterableOnce[A] with Product with Serializable

Represents optional values.

Represents optional values. Instances of Option are either an instance of $some or the object $none.

The most idiomatic way to use an $option instance is to treat it as a collection or monad and use map,flatMap, filter, or foreach:

val name: Option[String] = request getParameter "name"
val upper = name map { _.trim } filter { _.length != 0 } map { _.toUpperCase }
println(upper getOrElse "")

Note that this is equivalent to

val upper = for {
  name <- request getParameter "name"
  trimmed <- Some(name.trim)
  upper <- Some(trimmed.toUpperCase) if trimmed.length != 0
} yield upper
println(upper getOrElse "")

Because of how for comprehension works, if $none is returned from request.getParameter, the entire expression results in $none

This allows for sophisticated chaining of $option values without having to check for the existence of a value.

These are useful methods that exist for both $some and $none. - isDefined — True if not empty - isEmpty — True if empty - nonEmpty — True if not empty - orElse — Evaluate and return alternate optional value if empty - getOrElse — Evaluate and return alternate value if empty - get — Return value, throw exception if empty - fold — Apply function on optional value, return default if empty - map — Apply a function on the optional value - flatMap — Same as map but function must return an optional value - foreach — Apply a procedure on option value - collect — Apply partial pattern match on optional value - filter — An optional value satisfies predicate - filterNot — An optional value doesn't satisfy predicate - exists — Apply predicate on optional value, or false if empty - forall — Apply predicate on optional value, or true if empty - contains — Checks if value equals optional value, or false if empty - zip — Combine two optional values to make a paired optional value - unzip — Split an optional pair to two optional values - unzip3 — Split an optional triple to three optional values - toList — Unary list of optional value, otherwise the empty list

A less-idiomatic way to use $option values is via pattern matching:

val nameMaybe = request getParameter "name"
nameMaybe match {
  case Some(name) =>
    println(name.trim.toUppercase)
  case None =>
    println("No name value")
}

Interacting with code that can occasionally return null can be safely wrapped in $option to become $none and $some otherwise.

val abc = new java.util.HashMap[Int, String]
abc.put(1, "A")
bMaybe = Option(abc.get(2))
bMaybe match {
 case Some(b) =>
   println(s"Found $b")
 case None =>
   println("Not found")
}
Note:

Many of the methods in here are duplicative with those in the Traversable hierarchy, but they are duplicated for a reason: the implicit conversion tends to leave one with an Iterable in situations where one could have retained an Option.

Companion:
object
Source:
Option.scala
trait PartialFunction[-A, +B] extends A => B

A partial function of type PartialFunction[A, B] is a unary function where the domain does not necessarily include all values of type A.

A partial function of type PartialFunction[A, B] is a unary function where the domain does not necessarily include all values of type A. The function isDefinedAt allows to test dynamically if a value is in the domain of the function.

Even if isDefinedAt returns true for an a: A, calling apply(a) may still throw an exception, so the following code is legal:

val f: PartialFunction[Int, Any] = { case x => x / 0 }   // ArithmeticException: / by zero

It is the responsibility of the caller to call isDefinedAt before calling apply, because if isDefinedAt is false, it is not guaranteed apply will throw an exception to indicate an error condition. If an exception is not thrown, evaluation may result in an arbitrary value.

The usual way to respect this contract is to call applyOrElse, which is expected to be more efficient than calling both isDefinedAt and apply.

The main distinction between PartialFunction and scala.Function1 is that the user of a PartialFunction may choose to do something different with input that is declared to be outside its domain. For example:

val sample = 1 to 10
def isEven(n: Int) = n % 2 == 0
val eveningNews: PartialFunction[Int, String] = {
  case x if isEven(x) => s"$x is even"
}

// The method collect is described as "filter + map"
// because it uses a PartialFunction to select elements
// to which the function is applied.
val evenNumbers = sample.collect(eveningNews)

val oddlyEnough: PartialFunction[Int, String] = {
  case x if !isEven(x) => s"$x is odd"
}

// The method orElse allows chaining another PartialFunction
// to handle input outside the declared domain.
val numbers = sample.map(eveningNews orElse oddlyEnough)

// same as
val numbers = sample.map(n => eveningNews.applyOrElse(n, oddlyEnough))

val half: PartialFunction[Int, Int] = {
  case x if isEven(x) => x / 2
}

// Calculating the domain of a composition can be expensive.
val oddByHalf = half.andThen(oddlyEnough)

// Invokes `half.apply` on even elements!
val oddBalls = sample.filter(oddByHalf.isDefinedAt)

// Better than filter(oddByHalf.isDefinedAt).map(oddByHalf)
val oddBalls = sample.collect(oddByHalf)

// Providing "default" values.
val oddsAndEnds = sample.map(n => oddByHalf.applyOrElse(n, (i: Int) => s"[$i]"))
Note:

Optional Functions, PartialFunctions and extractor objects can be converted to each other as shown in the following table.  

How to convert ...

to a PartialFunction

to an optional Function

to an extractor

from a PartialFunction

Predef.identity

lift

Predef.identity

from optional Function

Function1.UnliftOps#unlift or Function.unlift

Predef.identity

Function1.UnliftOps#unlift

from an extractor

{ case extractor(x) => x }

extractor.unapply _

Predef.identity

 

Companion:
object
Source:
PartialFunction.scala

A few handy operations which leverage the extra bit of information available in partial functions.

A few handy operations which leverage the extra bit of information available in partial functions. Examples:

import PartialFunction._

def strangeConditional(other: Any): Boolean = cond(other) {
  case x: String if x == "abc" || x == "def"  => true
  case x: Int => true
}
def onlyInt(v: Any): Option[Int] = condOpt(v) { case x: Int => x }
Companion:
class
Source:
PartialFunction.scala

Marker trait for polymorphic function types.

Marker trait for polymorphic function types.

This is the only trait that can be refined with a polymorphic method, as long as that method is called apply, e.g.: PolyFunction { def apply[T_1, ..., T_M](x_1: P_1, ..., x_N: P_N): R } This type will be erased to FunctionN.

Source:
PolyFunction.scala
object Predef

The Predef object provides definitions that are accessible in all Scala compilation units without explicit qualification.

The Predef object provides definitions that are accessible in all Scala compilation units without explicit qualification.

Commonly Used Types

Predef provides type aliases for types which are commonly used, such as the immutable collection types scala.collection.immutable.Map and scala.collection.immutable.Set.

Console Output

For basic console output, Predef provides convenience methods print and println, which are aliases of the methods in the object scala.Console.

Assertions

A set of assert functions are provided for use as a way to document and dynamically check invariants in code. Invocations of assert can be elided at compile time by providing the command line option -Xdisable-assertions, which raises -Xelide-below above elidable.ASSERTION, to the scalac command.

Variants of assert intended for use with static analysis tools are also provided: assume, require and ensuring. require and ensuring are intended for use as a means of design-by-contract style specification of pre- and post-conditions on functions, with the intention that these specifications could be consumed by a static analysis tool. For instance,

def addNaturals(nats: List[Int]): Int = {
  require(nats forall (_ >= 0), "List contains negative numbers")
  nats.foldLeft(0)(_ + _)
} ensuring(_ >= 0)

The declaration of addNaturals states that the list of integers passed should only contain natural numbers (i.e. non-negative), and that the result returned will also be natural. require is distinct from assert in that if the condition fails, then the caller of the function is to blame rather than a logical error having been made within addNaturals itself. ensuring is a form of assert that declares the guarantee the function is providing with regards to its return value.

Implicit Conversions

A number of commonly applied implicit conversions are also defined here, and in the parent type scala.LowPriorityImplicits. Implicit conversions are provided for the "widening" of numeric values, for instance, converting a Short value to a Long value as required, and to add additional higher-order functions to Array values. These are described in more detail in the documentation of scala.Array.

Source:
Predef.scala
trait Product extends Equals

Base trait for all products, which in the standard library include at least scala.Product1 through scala.Product22 and therefore also their subclasses scala.Tuple1 through scala.Tuple22.

Base trait for all products, which in the standard library include at least scala.Product1 through scala.Product22 and therefore also their subclasses scala.Tuple1 through scala.Tuple22. In addition, all case classes implement Product with synthetically generated methods.

Source:
Product.scala
object Product1
Companion:
class
Source:
Product1.scala
trait Product1[+T1] extends Product

Product1 is a Cartesian product of 1 component.

Product1 is a Cartesian product of 1 component.

Companion:
object
Source:
Product1.scala
object Product10
Companion:
class
Source:
Product10.scala
trait Product10[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10] extends Product

Product10 is a Cartesian product of 10 components.

Product10 is a Cartesian product of 10 components.

Companion:
object
Source:
Product10.scala
object Product11
Companion:
class
Source:
Product11.scala
trait Product11[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11] extends Product

Product11 is a Cartesian product of 11 components.

Product11 is a Cartesian product of 11 components.

Companion:
object
Source:
Product11.scala
object Product12
Companion:
class
Source:
Product12.scala
trait Product12[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12] extends Product

Product12 is a Cartesian product of 12 components.

Product12 is a Cartesian product of 12 components.

Companion:
object
Source:
Product12.scala
object Product13
Companion:
class
Source:
Product13.scala
trait Product13[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13] extends Product

Product13 is a Cartesian product of 13 components.

Product13 is a Cartesian product of 13 components.

Companion:
object
Source:
Product13.scala
object Product14
Companion:
class
Source:
Product14.scala
trait Product14[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14] extends Product

Product14 is a Cartesian product of 14 components.

Product14 is a Cartesian product of 14 components.

Companion:
object
Source:
Product14.scala
object Product15
Companion:
class
Source:
Product15.scala
trait Product15[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15] extends Product

Product15 is a Cartesian product of 15 components.

Product15 is a Cartesian product of 15 components.

Companion:
object
Source:
Product15.scala
object Product16
Companion:
class
Source:
Product16.scala
trait Product16[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16] extends Product

Product16 is a Cartesian product of 16 components.

Product16 is a Cartesian product of 16 components.

Companion:
object
Source:
Product16.scala
object Product17
Companion:
class
Source:
Product17.scala
trait Product17[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16, +T17] extends Product

Product17 is a Cartesian product of 17 components.

Product17 is a Cartesian product of 17 components.

Companion:
object
Source:
Product17.scala
object Product18
Companion:
class
Source:
Product18.scala
trait Product18[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16, +T17, +T18] extends Product

Product18 is a Cartesian product of 18 components.

Product18 is a Cartesian product of 18 components.

Companion:
object
Source:
Product18.scala
object Product19
Companion:
class
Source:
Product19.scala
trait Product19[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16, +T17, +T18, +T19] extends Product

Product19 is a Cartesian product of 19 components.

Product19 is a Cartesian product of 19 components.

Companion:
object
Source:
Product19.scala
object Product2
Companion:
class
Source:
Product2.scala
trait Product2[+T1, +T2] extends Product

Product2 is a Cartesian product of 2 components.

Product2 is a Cartesian product of 2 components.

Companion:
object
Source:
Product2.scala
object Product20
Companion:
class
Source:
Product20.scala
trait Product20[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16, +T17, +T18, +T19, +T20] extends Product

Product20 is a Cartesian product of 20 components.

Product20 is a Cartesian product of 20 components.

Companion:
object
Source:
Product20.scala
object Product21
Companion:
class
Source:
Product21.scala
trait Product21[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16, +T17, +T18, +T19, +T20, +T21] extends Product

Product21 is a Cartesian product of 21 components.

Product21 is a Cartesian product of 21 components.

Companion:
object
Source:
Product21.scala
object Product22
Companion:
class
Source:
Product22.scala
trait Product22[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16, +T17, +T18, +T19, +T20, +T21, +T22] extends Product

Product22 is a Cartesian product of 22 components.

Product22 is a Cartesian product of 22 components.

Companion:
object
Source:
Product22.scala
object Product3
Companion:
class
Source:
Product3.scala
trait Product3[+T1, +T2, +T3] extends Product

Product3 is a Cartesian product of 3 components.

Product3 is a Cartesian product of 3 components.

Companion:
object
Source:
Product3.scala
object Product4
Companion:
class
Source:
Product4.scala
trait Product4[+T1, +T2, +T3, +T4] extends Product

Product4 is a Cartesian product of 4 components.

Product4 is a Cartesian product of 4 components.

Companion:
object
Source:
Product4.scala
object Product5
Companion:
class
Source:
Product5.scala
trait Product5[+T1, +T2, +T3, +T4, +T5] extends Product

Product5 is a Cartesian product of 5 components.

Product5 is a Cartesian product of 5 components.

Companion:
object
Source:
Product5.scala
object Product6
Companion:
class
Source:
Product6.scala
trait Product6[+T1, +T2, +T3, +T4, +T5, +T6] extends Product

Product6 is a Cartesian product of 6 components.

Product6 is a Cartesian product of 6 components.

Companion:
object
Source:
Product6.scala
object Product7
Companion:
class
Source:
Product7.scala
trait Product7[+T1, +T2, +T3, +T4, +T5, +T6, +T7] extends Product

Product7 is a Cartesian product of 7 components.

Product7 is a Cartesian product of 7 components.

Companion:
object
Source:
Product7.scala
object Product8
Companion:
class
Source:
Product8.scala
trait Product8[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8] extends Product

Product8 is a Cartesian product of 8 components.

Product8 is a Cartesian product of 8 components.

Companion:
object
Source:
Product8.scala
object Product9
Companion:
class
Source:
Product9.scala
trait Product9[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9] extends Product

Product9 is a Cartesian product of 9 components.

Product9 is a Cartesian product of 9 components.

Companion:
object
Source:
Product9.scala
case class ScalaReflectionException(msg: String) extends Exception

An exception that indicates an error during Scala reflection

An exception that indicates an error during Scala reflection

Source:
package.scala

A marker trait for objects that support structural selection via selectDynamic and applyDynamic

A marker trait for objects that support structural selection via selectDynamic and applyDynamic

Implementation classes should define, or make available as extension methods, the following two method signatures:

def selectDynamic(name: String): Any def applyDynamic(name: String)(args: Any*): Any =

selectDynamic is invoked for simple selections v.m, whereas applyDynamic is invoked for selections with arguments v.m(...). If there's only one kind of selection, the method supporting the other may be omitted. The applyDynamic can also have a second parameter list of java.lang.Class arguments, i.e. it may alternatively have the signature

def applyDynamic(name: String, paramClasses: Class[_])(args: Any): Any

In this case the call will synthesize Class arguments for the erasure of all formal parameter types of the method in the structural type.

Companion:
object
Source:
Selectable.scala
object Selectable
Companion:
class
Source:
Selectable.scala

Annotation for specifying the serialVersionUID field of a (serializable) class.

Annotation for specifying the serialVersionUID field of a (serializable) class.

On the JVM, a class with this annotation will receive a private, static, and final field called serialVersionUID with the provided value, which the JVM's serialization mechanism uses to determine serialization compatibility between different versions of a class.

See also:
Source:
SerialVersionUID.scala
final abstract class Short extends AnyVal

Short, a 16-bit signed integer (equivalent to Java's short primitive type) is a subtype of scala.AnyVal.

Short, a 16-bit signed integer (equivalent to Java's short primitive type) is a subtype of scala.AnyVal. Instances of Short are not represented by an object in the underlying runtime system.

There is an implicit conversion from scala.Short => scala.runtime.RichShort which provides useful non-primitive operations.

Companion:
object
Source:
Short.scala
object Short
Companion:
class
Source:
Short.scala
final open class Singleton

Singleton is used by the compiler as a supertype for singleton types.

Singleton is used by the compiler as a supertype for singleton types. This includes literal types, as they are also singleton types.

scala> object A { val x = 42 }
defined object A

scala> implicitly[A.type <:< Singleton]
res12: A.type <:< Singleton = generalized constraint

scala> implicitly[A.x.type <:< Singleton]
res13: A.x.type <:< Singleton = generalized constraint

scala> implicitly[42 <:< Singleton]
res14: 42 <:< Singleton = generalized constraint

scala> implicitly[Int <:< Singleton]
^
error: Cannot prove that Int <:< Singleton.

Singleton has a special meaning when it appears as an upper bound on a formal type parameter. Normally, type inference in Scala widens singleton types to the underlying non-singleton type. When a type parameter has an explicit upper bound of Singleton, the compiler infers a singleton type.

scala> def check42[T](x: T)(implicit ev: T =:= 42): T = x
check42: [T](x: T)(implicit ev: T =:= 42)T

scala> val x1 = check42(42)
^
error: Cannot prove that Int =:= 42.

scala> def singleCheck42[T <: Singleton](x: T)(implicit ev: T =:= 42): T = x
singleCheck42: [T <: Singleton](x: T)(implicit ev: T =:= 42)T

scala> val x2 = singleCheck42(42)
x2: Int = 42

See also SIP-23 about Literal-based Singleton Types.

final case class Some[+A](value: A) extends Option[A]

Class Some[A] represents existing values of type A.

Class Some[A] represents existing values of type A.

Source:
Option.scala

A common supertype for companions of specializable types.

A common supertype for companions of specializable types. Should not be extended in user code.

Companion:
object
Source:
Specializable.scala
case class StringContext(parts: String*)

This class provides the basic mechanism to do String Interpolation.

This class provides the basic mechanism to do String Interpolation. String Interpolation allows users to embed variable references directly in *processed* string literals. Here's an example:

val name = "James"
println(s"Hello, $name")  // Hello, James

Any processed string literal is rewritten as an instantiation and method call against this class. For example:

s"Hello, $name"

is rewritten to be:

StringContext("Hello, ", "").s(name)

By default, this class provides the raw, s and f methods as available interpolators.

To provide your own string interpolator, create an implicit class which adds a method to StringContext. Here's an example:

implicit class JsonHelper(private val sc: StringContext) extends AnyVal {
  def json(args: Any*): JSONObject = ...
}
val x: JSONObject = json"{ a: $a }"

Here the JsonHelper extension class implicitly adds the json method to StringContext which can be used for json string literals.

Value parameters:
parts

The parts that make up the interpolated string, without the expressions that get inserted by interpolation.

Companion:
object
Source:
StringContext.scala
final class Symbol extends Serializable

This class provides a simple way to get unique objects for equal strings.

This class provides a simple way to get unique objects for equal strings. Since symbols are interned, they can be compared using reference equality.

Companion:
object
Source:
Symbol.scala
object Symbol
Companion:
class
Source:
Symbol.scala
sealed trait Tuple extends Product

Tuple of arbitrary arity

Tuple of arbitrary arity

Companion:
object
Source:
Tuple.scala
object Tuple
Companion:
class
Source:
Tuple.scala
final case class Tuple1[+T1](_1: T1) extends Product1[T1]

A tuple of 1 elements; the canonical representation of a scala.Product1.

A tuple of 1 elements; the canonical representation of a scala.Product1.

Value parameters:
_1

Element 1 of this Tuple1

Constructor:

Create a new tuple with 1 elements.

Source:
Tuple1.scala
final case class Tuple10[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10) extends Product10[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10]

A tuple of 10 elements; the canonical representation of a scala.Product10.

A tuple of 10 elements; the canonical representation of a scala.Product10.

Value parameters:
_1

Element 1 of this Tuple10

_10

Element 10 of this Tuple10

_2

Element 2 of this Tuple10

_3

Element 3 of this Tuple10

_4

Element 4 of this Tuple10

_5

Element 5 of this Tuple10

_6

Element 6 of this Tuple10

_7

Element 7 of this Tuple10

_8

Element 8 of this Tuple10

_9

Element 9 of this Tuple10

Constructor:

Create a new tuple with 10 elements. Note that it is more idiomatic to create a Tuple10 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10)

Source:
Tuple10.scala
final case class Tuple11[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10, _11: T11) extends Product11[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11]

A tuple of 11 elements; the canonical representation of a scala.Product11.

A tuple of 11 elements; the canonical representation of a scala.Product11.

Value parameters:
_1

Element 1 of this Tuple11

_10

Element 10 of this Tuple11

_11

Element 11 of this Tuple11

_2

Element 2 of this Tuple11

_3

Element 3 of this Tuple11

_4

Element 4 of this Tuple11

_5

Element 5 of this Tuple11

_6

Element 6 of this Tuple11

_7

Element 7 of this Tuple11

_8

Element 8 of this Tuple11

_9

Element 9 of this Tuple11

Constructor:

Create a new tuple with 11 elements. Note that it is more idiomatic to create a Tuple11 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11)

Source:
Tuple11.scala
final case class Tuple12[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10, _11: T11, _12: T12) extends Product12[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11, T12]

A tuple of 12 elements; the canonical representation of a scala.Product12.

A tuple of 12 elements; the canonical representation of a scala.Product12.

Value parameters:
_1

Element 1 of this Tuple12

_10

Element 10 of this Tuple12

_11

Element 11 of this Tuple12

_12

Element 12 of this Tuple12

_2

Element 2 of this Tuple12

_3

Element 3 of this Tuple12

_4

Element 4 of this Tuple12

_5

Element 5 of this Tuple12

_6

Element 6 of this Tuple12

_7

Element 7 of this Tuple12

_8

Element 8 of this Tuple12

_9

Element 9 of this Tuple12

Constructor:

Create a new tuple with 12 elements. Note that it is more idiomatic to create a Tuple12 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12)

Source:
Tuple12.scala
final case class Tuple13[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10, _11: T11, _12: T12, _13: T13) extends Product13[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11, T12, T13]

A tuple of 13 elements; the canonical representation of a scala.Product13.

A tuple of 13 elements; the canonical representation of a scala.Product13.

Value parameters:
_1

Element 1 of this Tuple13

_10

Element 10 of this Tuple13

_11

Element 11 of this Tuple13

_12

Element 12 of this Tuple13

_13

Element 13 of this Tuple13

_2

Element 2 of this Tuple13

_3

Element 3 of this Tuple13

_4

Element 4 of this Tuple13

_5

Element 5 of this Tuple13

_6

Element 6 of this Tuple13

_7

Element 7 of this Tuple13

_8

Element 8 of this Tuple13

_9

Element 9 of this Tuple13

Constructor:

Create a new tuple with 13 elements. Note that it is more idiomatic to create a Tuple13 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13)

Source:
Tuple13.scala
final case class Tuple14[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10, _11: T11, _12: T12, _13: T13, _14: T14) extends Product14[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11, T12, T13, T14]

A tuple of 14 elements; the canonical representation of a scala.Product14.

A tuple of 14 elements; the canonical representation of a scala.Product14.

Value parameters:
_1

Element 1 of this Tuple14

_10

Element 10 of this Tuple14

_11

Element 11 of this Tuple14

_12

Element 12 of this Tuple14

_13

Element 13 of this Tuple14

_14

Element 14 of this Tuple14

_2

Element 2 of this Tuple14

_3

Element 3 of this Tuple14

_4

Element 4 of this Tuple14

_5

Element 5 of this Tuple14

_6

Element 6 of this Tuple14

_7

Element 7 of this Tuple14

_8

Element 8 of this Tuple14

_9

Element 9 of this Tuple14

Constructor:

Create a new tuple with 14 elements. Note that it is more idiomatic to create a Tuple14 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13, t14)

Source:
Tuple14.scala
final case class Tuple15[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10, _11: T11, _12: T12, _13: T13, _14: T14, _15: T15) extends Product15[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11, T12, T13, T14, T15]

A tuple of 15 elements; the canonical representation of a scala.Product15.

A tuple of 15 elements; the canonical representation of a scala.Product15.

Value parameters:
_1

Element 1 of this Tuple15

_10

Element 10 of this Tuple15

_11

Element 11 of this Tuple15

_12

Element 12 of this Tuple15

_13

Element 13 of this Tuple15

_14

Element 14 of this Tuple15

_15

Element 15 of this Tuple15

_2

Element 2 of this Tuple15

_3

Element 3 of this Tuple15

_4

Element 4 of this Tuple15

_5

Element 5 of this Tuple15

_6

Element 6 of this Tuple15

_7

Element 7 of this Tuple15

_8

Element 8 of this Tuple15

_9

Element 9 of this Tuple15

Constructor:

Create a new tuple with 15 elements. Note that it is more idiomatic to create a Tuple15 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13, t14, t15)

Source:
Tuple15.scala
final case class Tuple16[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10, _11: T11, _12: T12, _13: T13, _14: T14, _15: T15, _16: T16) extends Product16[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11, T12, T13, T14, T15, T16]

A tuple of 16 elements; the canonical representation of a scala.Product16.

A tuple of 16 elements; the canonical representation of a scala.Product16.

Value parameters:
_1

Element 1 of this Tuple16

_10

Element 10 of this Tuple16

_11

Element 11 of this Tuple16

_12

Element 12 of this Tuple16

_13

Element 13 of this Tuple16

_14

Element 14 of this Tuple16

_15

Element 15 of this Tuple16

_16

Element 16 of this Tuple16

_2

Element 2 of this Tuple16

_3

Element 3 of this Tuple16

_4

Element 4 of this Tuple16

_5

Element 5 of this Tuple16

_6

Element 6 of this Tuple16

_7

Element 7 of this Tuple16

_8

Element 8 of this Tuple16

_9

Element 9 of this Tuple16

Constructor:

Create a new tuple with 16 elements. Note that it is more idiomatic to create a Tuple16 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13, t14, t15, t16)

Source:
Tuple16.scala
final case class Tuple17[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16, +T17](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10, _11: T11, _12: T12, _13: T13, _14: T14, _15: T15, _16: T16, _17: T17) extends Product17[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11, T12, T13, T14, T15, T16, T17]

A tuple of 17 elements; the canonical representation of a scala.Product17.

A tuple of 17 elements; the canonical representation of a scala.Product17.

Value parameters:
_1

Element 1 of this Tuple17

_10

Element 10 of this Tuple17

_11

Element 11 of this Tuple17

_12

Element 12 of this Tuple17

_13

Element 13 of this Tuple17

_14

Element 14 of this Tuple17

_15

Element 15 of this Tuple17

_16

Element 16 of this Tuple17

_17

Element 17 of this Tuple17

_2

Element 2 of this Tuple17

_3

Element 3 of this Tuple17

_4

Element 4 of this Tuple17

_5

Element 5 of this Tuple17

_6

Element 6 of this Tuple17

_7

Element 7 of this Tuple17

_8

Element 8 of this Tuple17

_9

Element 9 of this Tuple17

Constructor:

Create a new tuple with 17 elements. Note that it is more idiomatic to create a Tuple17 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13, t14, t15, t16, t17)

Source:
Tuple17.scala
final case class Tuple18[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16, +T17, +T18](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10, _11: T11, _12: T12, _13: T13, _14: T14, _15: T15, _16: T16, _17: T17, _18: T18) extends Product18[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11, T12, T13, T14, T15, T16, T17, T18]

A tuple of 18 elements; the canonical representation of a scala.Product18.

A tuple of 18 elements; the canonical representation of a scala.Product18.

Value parameters:
_1

Element 1 of this Tuple18

_10

Element 10 of this Tuple18

_11

Element 11 of this Tuple18

_12

Element 12 of this Tuple18

_13

Element 13 of this Tuple18

_14

Element 14 of this Tuple18

_15

Element 15 of this Tuple18

_16

Element 16 of this Tuple18

_17

Element 17 of this Tuple18

_18

Element 18 of this Tuple18

_2

Element 2 of this Tuple18

_3

Element 3 of this Tuple18

_4

Element 4 of this Tuple18

_5

Element 5 of this Tuple18

_6

Element 6 of this Tuple18

_7

Element 7 of this Tuple18

_8

Element 8 of this Tuple18

_9

Element 9 of this Tuple18

Constructor:

Create a new tuple with 18 elements. Note that it is more idiomatic to create a Tuple18 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13, t14, t15, t16, t17, t18)

Source:
Tuple18.scala
final case class Tuple19[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16, +T17, +T18, +T19](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10, _11: T11, _12: T12, _13: T13, _14: T14, _15: T15, _16: T16, _17: T17, _18: T18, _19: T19) extends Product19[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11, T12, T13, T14, T15, T16, T17, T18, T19]

A tuple of 19 elements; the canonical representation of a scala.Product19.

A tuple of 19 elements; the canonical representation of a scala.Product19.

Value parameters:
_1

Element 1 of this Tuple19

_10

Element 10 of this Tuple19

_11

Element 11 of this Tuple19

_12

Element 12 of this Tuple19

_13

Element 13 of this Tuple19

_14

Element 14 of this Tuple19

_15

Element 15 of this Tuple19

_16

Element 16 of this Tuple19

_17

Element 17 of this Tuple19

_18

Element 18 of this Tuple19

_19

Element 19 of this Tuple19

_2

Element 2 of this Tuple19

_3

Element 3 of this Tuple19

_4

Element 4 of this Tuple19

_5

Element 5 of this Tuple19

_6

Element 6 of this Tuple19

_7

Element 7 of this Tuple19

_8

Element 8 of this Tuple19

_9

Element 9 of this Tuple19

Constructor:

Create a new tuple with 19 elements. Note that it is more idiomatic to create a Tuple19 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13, t14, t15, t16, t17, t18, t19)

Source:
Tuple19.scala
final case class Tuple2[+T1, +T2](_1: T1, _2: T2) extends Product2[T1, T2]

A tuple of 2 elements; the canonical representation of a scala.Product2.

A tuple of 2 elements; the canonical representation of a scala.Product2.

Value parameters:
_1

Element 1 of this Tuple2

_2

Element 2 of this Tuple2

Constructor:

Create a new tuple with 2 elements. Note that it is more idiomatic to create a Tuple2 via (t1, t2)

Source:
Tuple2.scala
final case class Tuple20[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16, +T17, +T18, +T19, +T20](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10, _11: T11, _12: T12, _13: T13, _14: T14, _15: T15, _16: T16, _17: T17, _18: T18, _19: T19, _20: T20) extends Product20[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11, T12, T13, T14, T15, T16, T17, T18, T19, T20]

A tuple of 20 elements; the canonical representation of a scala.Product20.

A tuple of 20 elements; the canonical representation of a scala.Product20.

Value parameters:
_1

Element 1 of this Tuple20

_10

Element 10 of this Tuple20

_11

Element 11 of this Tuple20

_12

Element 12 of this Tuple20

_13

Element 13 of this Tuple20

_14

Element 14 of this Tuple20

_15

Element 15 of this Tuple20

_16

Element 16 of this Tuple20

_17

Element 17 of this Tuple20

_18

Element 18 of this Tuple20

_19

Element 19 of this Tuple20

_2

Element 2 of this Tuple20

_20

Element 20 of this Tuple20

_3

Element 3 of this Tuple20

_4

Element 4 of this Tuple20

_5

Element 5 of this Tuple20

_6

Element 6 of this Tuple20

_7

Element 7 of this Tuple20

_8

Element 8 of this Tuple20

_9

Element 9 of this Tuple20

Constructor:

Create a new tuple with 20 elements. Note that it is more idiomatic to create a Tuple20 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13, t14, t15, t16, t17, t18, t19, t20)

Source:
Tuple20.scala
final case class Tuple21[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16, +T17, +T18, +T19, +T20, +T21](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10, _11: T11, _12: T12, _13: T13, _14: T14, _15: T15, _16: T16, _17: T17, _18: T18, _19: T19, _20: T20, _21: T21) extends Product21[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11, T12, T13, T14, T15, T16, T17, T18, T19, T20, T21]

A tuple of 21 elements; the canonical representation of a scala.Product21.

A tuple of 21 elements; the canonical representation of a scala.Product21.

Value parameters:
_1

Element 1 of this Tuple21

_10

Element 10 of this Tuple21

_11

Element 11 of this Tuple21

_12

Element 12 of this Tuple21

_13

Element 13 of this Tuple21

_14

Element 14 of this Tuple21

_15

Element 15 of this Tuple21

_16

Element 16 of this Tuple21

_17

Element 17 of this Tuple21

_18

Element 18 of this Tuple21

_19

Element 19 of this Tuple21

_2

Element 2 of this Tuple21

_20

Element 20 of this Tuple21

_21

Element 21 of this Tuple21

_3

Element 3 of this Tuple21

_4

Element 4 of this Tuple21

_5

Element 5 of this Tuple21

_6

Element 6 of this Tuple21

_7

Element 7 of this Tuple21

_8

Element 8 of this Tuple21

_9

Element 9 of this Tuple21

Constructor:

Create a new tuple with 21 elements. Note that it is more idiomatic to create a Tuple21 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13, t14, t15, t16, t17, t18, t19, t20, t21)

Source:
Tuple21.scala
final case class Tuple22[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9, +T10, +T11, +T12, +T13, +T14, +T15, +T16, +T17, +T18, +T19, +T20, +T21, +T22](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9, _10: T10, _11: T11, _12: T12, _13: T13, _14: T14, _15: T15, _16: T16, _17: T17, _18: T18, _19: T19, _20: T20, _21: T21, _22: T22) extends Product22[T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11, T12, T13, T14, T15, T16, T17, T18, T19, T20, T21, T22]

A tuple of 22 elements; the canonical representation of a scala.Product22.

A tuple of 22 elements; the canonical representation of a scala.Product22.

Value parameters:
_1

Element 1 of this Tuple22

_10

Element 10 of this Tuple22

_11

Element 11 of this Tuple22

_12

Element 12 of this Tuple22

_13

Element 13 of this Tuple22

_14

Element 14 of this Tuple22

_15

Element 15 of this Tuple22

_16

Element 16 of this Tuple22

_17

Element 17 of this Tuple22

_18

Element 18 of this Tuple22

_19

Element 19 of this Tuple22

_2

Element 2 of this Tuple22

_20

Element 20 of this Tuple22

_21

Element 21 of this Tuple22

_22

Element 22 of this Tuple22

_3

Element 3 of this Tuple22

_4

Element 4 of this Tuple22

_5

Element 5 of this Tuple22

_6

Element 6 of this Tuple22

_7

Element 7 of this Tuple22

_8

Element 8 of this Tuple22

_9

Element 9 of this Tuple22

Constructor:

Create a new tuple with 22 elements. Note that it is more idiomatic to create a Tuple22 via (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13, t14, t15, t16, t17, t18, t19, t20, t21, t22)

Source:
Tuple22.scala
final case class Tuple3[+T1, +T2, +T3](_1: T1, _2: T2, _3: T3) extends Product3[T1, T2, T3]

A tuple of 3 elements; the canonical representation of a scala.Product3.

A tuple of 3 elements; the canonical representation of a scala.Product3.

Value parameters:
_1

Element 1 of this Tuple3

_2

Element 2 of this Tuple3

_3

Element 3 of this Tuple3

Constructor:

Create a new tuple with 3 elements. Note that it is more idiomatic to create a Tuple3 via (t1, t2, t3)

Source:
Tuple3.scala
final case class Tuple4[+T1, +T2, +T3, +T4](_1: T1, _2: T2, _3: T3, _4: T4) extends Product4[T1, T2, T3, T4]

A tuple of 4 elements; the canonical representation of a scala.Product4.

A tuple of 4 elements; the canonical representation of a scala.Product4.

Value parameters:
_1

Element 1 of this Tuple4

_2

Element 2 of this Tuple4

_3

Element 3 of this Tuple4

_4

Element 4 of this Tuple4

Constructor:

Create a new tuple with 4 elements. Note that it is more idiomatic to create a Tuple4 via (t1, t2, t3, t4)

Source:
Tuple4.scala
final case class Tuple5[+T1, +T2, +T3, +T4, +T5](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5) extends Product5[T1, T2, T3, T4, T5]

A tuple of 5 elements; the canonical representation of a scala.Product5.

A tuple of 5 elements; the canonical representation of a scala.Product5.

Value parameters:
_1

Element 1 of this Tuple5

_2

Element 2 of this Tuple5

_3

Element 3 of this Tuple5

_4

Element 4 of this Tuple5

_5

Element 5 of this Tuple5

Constructor:

Create a new tuple with 5 elements. Note that it is more idiomatic to create a Tuple5 via (t1, t2, t3, t4, t5)

Source:
Tuple5.scala
final case class Tuple6[+T1, +T2, +T3, +T4, +T5, +T6](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6) extends Product6[T1, T2, T3, T4, T5, T6]

A tuple of 6 elements; the canonical representation of a scala.Product6.

A tuple of 6 elements; the canonical representation of a scala.Product6.

Value parameters:
_1

Element 1 of this Tuple6

_2

Element 2 of this Tuple6

_3

Element 3 of this Tuple6

_4

Element 4 of this Tuple6

_5

Element 5 of this Tuple6

_6

Element 6 of this Tuple6

Constructor:

Create a new tuple with 6 elements. Note that it is more idiomatic to create a Tuple6 via (t1, t2, t3, t4, t5, t6)

Source:
Tuple6.scala
final case class Tuple7[+T1, +T2, +T3, +T4, +T5, +T6, +T7](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7) extends Product7[T1, T2, T3, T4, T5, T6, T7]

A tuple of 7 elements; the canonical representation of a scala.Product7.

A tuple of 7 elements; the canonical representation of a scala.Product7.

Value parameters:
_1

Element 1 of this Tuple7

_2

Element 2 of this Tuple7

_3

Element 3 of this Tuple7

_4

Element 4 of this Tuple7

_5

Element 5 of this Tuple7

_6

Element 6 of this Tuple7

_7

Element 7 of this Tuple7

Constructor:

Create a new tuple with 7 elements. Note that it is more idiomatic to create a Tuple7 via (t1, t2, t3, t4, t5, t6, t7)

Source:
Tuple7.scala
final case class Tuple8[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8) extends Product8[T1, T2, T3, T4, T5, T6, T7, T8]

A tuple of 8 elements; the canonical representation of a scala.Product8.

A tuple of 8 elements; the canonical representation of a scala.Product8.

Value parameters:
_1

Element 1 of this Tuple8

_2

Element 2 of this Tuple8

_3

Element 3 of this Tuple8

_4

Element 4 of this Tuple8

_5

Element 5 of this Tuple8

_6

Element 6 of this Tuple8

_7

Element 7 of this Tuple8

_8

Element 8 of this Tuple8

Constructor:

Create a new tuple with 8 elements. Note that it is more idiomatic to create a Tuple8 via (t1, t2, t3, t4, t5, t6, t7, t8)

Source:
Tuple8.scala
final case class Tuple9[+T1, +T2, +T3, +T4, +T5, +T6, +T7, +T8, +T9](_1: T1, _2: T2, _3: T3, _4: T4, _5: T5, _6: T6, _7: T7, _8: T8, _9: T9) extends Product9[T1, T2, T3, T4, T5, T6, T7, T8, T9]

A tuple of 9 elements; the canonical representation of a scala.Product9.

A tuple of 9 elements; the canonical representation of a scala.Product9.

Value parameters:
_1

Element 1 of this Tuple9

_2

Element 2 of this Tuple9

_3

Element 3 of this Tuple9

_4

Element 4 of this Tuple9

_5

Element 5 of this Tuple9

_6

Element 6 of this Tuple9

_7

Element 7 of this Tuple9

_8

Element 8 of this Tuple9

_9

Element 9 of this Tuple9

Constructor:

Create a new tuple with 9 elements. Note that it is more idiomatic to create a Tuple9 via (t1, t2, t3, t4, t5, t6, t7, t8, t9)

Source:
Tuple9.scala
final case class UninitializedFieldError(msg: String) extends RuntimeException

This class implements errors which are thrown whenever a field is used before it has been initialized.

This class implements errors which are thrown whenever a field is used before it has been initialized.

Such runtime checks are not emitted by default. They can be enabled by the -Xcheckinit compiler option.

Source:
UninitializedFieldError.scala
final abstract class Unit extends AnyVal

Unit is a subtype of scala.AnyVal.

Unit is a subtype of scala.AnyVal. There is only one value of type Unit, (), and it is not represented by any object in the underlying runtime system. A method with return type Unit is analogous to a Java method which is declared void.

Companion:
object
Source:
Unit.scala
object Unit
Companion:
class
Source:
Unit.scala
final class ValueOf[T](val value: T) extends AnyVal

ValueOf[T] provides the unique value of the type T where T is a type which has a single inhabitant.

ValueOf[T] provides the unique value of the type T where T is a type which has a single inhabitant. Eligible types are singleton types of the form stablePath.type, Unit and singleton types corresponding to value literals.

Instances of ValueOf[T] are provided implicitly for all eligible types. Typically an instance would be required where a runtime value corresponding to a type level computation is needed.

For example, we might define a type Residue[M <: Int] corresponding to the group of integers modulo M. We could then mandate that residues can be summed only when they are parameterized by the same modulus,

case class Residue[M <: Int](n: Int) extends AnyVal {
 def +(rhs: Residue[M])(implicit m: ValueOf[M]): Residue[M] =
   Residue((this.n + rhs.n) % valueOf[M])
}

val fiveModTen = Residue[10](5)
val nineModTen = Residue[10](9)

fiveModTen + nineModTen    // OK == Residue[10](4)

val fourModEleven = Residue[11](4)

fiveModTen + fourModEleven // compiler error: type mismatch;
                          //   found   : Residue[11]
                          //   required: Residue[10]

Notice that here the modulus is encoded in the type of the values and so does not incur any additional per-value storage cost. When a runtime value of the modulus is required in the implementation of + it is provided at the call site via the implicit argument m of type ValueOf[M].

Source:
ValueOf.scala
class deprecated(message: String, since: String) extends ConstantAnnotation

An annotation that designates that a definition is deprecated.

An annotation that designates that a definition is deprecated. A deprecation warning is issued upon usage of the annotated definition.

Library authors should state the library's deprecation policy in their documentation to give developers guidance on how long a deprecated definition will be preserved.

Library authors should prepend the name of their library to the version number to help developers distinguish deprecations coming from different libraries:

@deprecated("this method will be removed", "FooLib 12.0")
def oldMethod(x: Int) = ...

The compiler will emit deprecation warnings grouped by library and version:

oldMethod(1)
oldMethod(2)
aDeprecatedMethodFromLibraryBar(3, 4)

// warning: there was one deprecation warning (since BarLib 3.2)
// warning: there were two deprecation warnings (since FooLib 12.0)
// warning: there were three deprecation warnings in total; re-run with -deprecation for details

@deprecated in the Scala language and its standard library

A deprecated element of the Scala language or a definition in the Scala standard library will be preserved at least for the current major version.

This means that an element deprecated in some 2.13.x release will be preserved in all 2.13.x releases, but may be removed in the future. (A deprecated element might be kept longer to ease migration, but developers should not rely on this.)

Value parameters:
message

the message to print during compilation if the definition is accessed

since

a string identifying the first version in which the definition was deprecated

See also:
Source:
deprecated.scala
final class deprecatedInheritance(message: String, since: String) extends ConstantAnnotation

An annotation that designates that inheriting from a class is deprecated.

An annotation that designates that inheriting from a class is deprecated.

This is usually done to warn about a non-final class being made final in a future version. Sub-classing such a class then generates a warning.

No warnings are generated if the subclass is in the same compilation unit.

Library authors should state the library's deprecation policy in their documentation to give developers guidance on when a type annotated with @deprecatedInheritance will be finalized.

Library authors should prepend the name of their library to the version number to help developers distinguish deprecations coming from different libraries:

@deprecatedInheritance("this class will be made final", "FooLib 12.0")
class Foo
val foo = new Foo     // no deprecation warning
class Bar extends Foo
// warning: inheritance from class Foo is deprecated (since FooLib 12.0): this class will be made final
// class Bar extends Foo
//                   ^
Value parameters:
message

the message to print during compilation if the class was sub-classed

since

a string identifying the first version in which inheritance was deprecated

See also:
Source:
deprecatedInheritance.scala
class deprecatedName(name: String, since: String) extends StaticAnnotation

An annotation that designates that the name of a parameter is deprecated.

An annotation that designates that the name of a parameter is deprecated.

Using this name in a named argument generates a deprecation warning.

Library authors should state the library's deprecation policy in their documentation to give developers guidance on how long a deprecated name will be preserved.

Library authors should prepend the name of their library to the version number to help developers distinguish deprecations coming from different libraries:

def inc(x: Int, @deprecatedName("y", "FooLib 12.0") n: Int): Int = x + n
inc(1, y = 2)

will produce the following warning:

warning: the parameter name y is deprecated (since FooLib 12.0): use n instead
inc(1, y = 2)
         ^
See also:
Source:
deprecatedName.scala
class deprecatedOverriding(message: String, since: String) extends ConstantAnnotation

An annotation that designates that overriding a member is deprecated.

An annotation that designates that overriding a member is deprecated.

Overriding such a member in a sub-class then generates a warning.

Library authors should state the library's deprecation policy in their documentation to give developers guidance on when a method annotated with @deprecatedOverriding will be finalized.

Library authors should prepend the name of their library to the version number to help developers distinguish deprecations coming from different libraries:

class Foo {
  @deprecatedOverriding("this method will be made final", "FooLib 12.0")
  def add(x: Int, y: Int) = x + y
}
class Bar extends Foo // no deprecation warning
class Baz extends Foo {
  override def add(x: Int, y: Int) = x - y
}
// warning: overriding method add in class Foo is deprecated (since FooLib 12.0): this method will be made final
// override def add(x: Int, y: Int) = x - y
//              ^
Value parameters:
message

the message to print during compilation if the member was overridden

since

a string identifying the first version in which overriding was deprecated

See also:
Source:
deprecatedOverriding.scala
class inline extends StaticAnnotation

An annotation for methods that the optimizer should inline.

An annotation for methods that the optimizer should inline.

Note that by default, the Scala optimizer is disabled and no callsites are inlined. See -opt:help for information on how to enable the optimizer and inliner.

When inlining is enabled, the inliner will always try to inline methods or callsites annotated @inline (under the condition that inlining from the defining class is allowed, see -opt-inline-from:help). If inlining is not possible, for example because the method is not final, an optimizer warning will be issued. See -opt-warnings:help for details.

Examples:

@inline   final def f1(x: Int) = x
@noinline final def f2(x: Int) = x
         final def f3(x: Int) = x

def t1 = f1(1)              // inlined if possible
def t2 = f2(1)              // not inlined
def t3 = f3(1)              // may be inlined (the inliner heuristics can select the callsite)
def t4 = f1(1): @noinline   // not inlined (override at callsite)
def t5 = f2(1): @inline     // inlined if possible (override at callsite)
def t6 = f3(1): @inline     // inlined if possible
def t7 = f3(1): @noinline   // not inlined
}

Note: parentheses are required when annotating a callsite within a larger expression.

def t1 = f1(1) + f1(1): @noinline   // equivalent to (f1(1) + f1(1)): @noinline
def t2 = f1(1) + (f1(1): @noinline) // the second call to f1 is not inlined
Source:
inline.scala
object language

The scala.language object controls the language features available to the programmer, as proposed in the SIP-18 document.

The scala.language object controls the language features available to the programmer, as proposed in the SIP-18 document.

Each of these features has to be explicitly imported into the current scope to become available:

import language.postfixOps // or language._
List(1, 2, 3) reverse

The language features are:

Source:
language.scala
class main extends Annotation

An annotation that designates a main function

An annotation that designates a main function

Source:
main.scala
class native extends StaticAnnotation

Marker for native methods.

Marker for native methods.

@native def f(x: Int, y: List[Long]): String = ...

A @native method is compiled to the platform's native method, while discarding the method's body (if any). The body will be type checked if present.

A method marked @native must be a member of a class, not a trait (since 2.12).

Source:
native.scala
final class noinline extends StaticAnnotation

An annotation for methods that the optimizer should not inline.

An annotation for methods that the optimizer should not inline.

Note that by default, the Scala optimizer is disabled and no callsites are inlined. See -opt:help for information how to enable the optimizer and inliner.

When inlining is enabled, the inliner will never inline methods or callsites annotated @noinline.

Examples:

@inline   final def f1(x: Int) = x
@noinline final def f2(x: Int) = x
         final def f3(x: Int) = x

def t1 = f1(1)              // inlined if possible
def t2 = f2(1)              // not inlined
def t3 = f3(1)              // may be inlined (the inliner heuristics can select the callsite)
def t4 = f1(1): @noinline   // not inlined (override at callsite)
def t5 = f2(1): @inline     // inlined if possible (override at callsite)
def t6 = f3(1): @inline     // inlined if possible
def t7 = f3(1): @noinline   // not inlined
}

Note: parentheses are required when annotating a callsite within a larger expression.

def t1 = f1(1) + f1(1): @noinline   // equivalent to (f1(1) + f1(1)): @noinline
def t2 = f1(1) + (f1(1): @noinline) // the second call to f1 is not inlined
Source:
noinline.scala
final class specialized(group: SpecializedGroup) extends StaticAnnotation

Annotate type parameters on which code should be automatically specialized.

Annotate type parameters on which code should be automatically specialized. For example:

class MyList[@specialized T] ...

Type T can be specialized on a subset of the primitive types by specifying a list of primitive types to specialize at:

class MyList[@specialized(Int, Double, Boolean) T] ..
Source:
specialized.scala
final class throws[T <: Throwable](cause: String) extends StaticAnnotation

Annotation for specifying the exceptions thrown by a method.

Annotation for specifying the exceptions thrown by a method. For example:

class Reader(fname: String) {
 private val in = new BufferedReader(new FileReader(fname))
 @throws[IOException]("if the file doesn't exist")
 def read() = in.read()
}
Source:
throws.scala
final class transient extends StaticAnnotation
final class unchecked extends Annotation

An annotation to designate that the annotated entity should not be considered for additional compiler checks.

An annotation to designate that the annotated entity should not be considered for additional compiler checks. Specific applications include annotating the subject of a match expression to suppress exhaustiveness and reachability warnings, and annotating a type argument in a match case to suppress unchecked warnings.

Such suppression should be used with caution, without which one may encounter scala.MatchError or java.lang.ClassCastException at runtime. In most cases one can and should address the warning instead of suppressing it.

object Test extends App {
  // This would normally warn "match is not exhaustive"
  // because `None` is not covered.
  def f(x: Option[String]) = (x: @unchecked) match { case Some(y) => y }
  // This would normally warn "type pattern is unchecked"
  // but here will blindly cast the head element to String.
  def g(xs: Any) = xs match { case x: List[String @unchecked] => x.head }
}
Source:
unchecked.scala
final class volatile extends StaticAnnotation

Deprecated classlikes

Classes and objects (but note, not traits) inheriting the DelayedInit marker trait will have their initialization code rewritten as follows: code becomes delayedInit(code).

Classes and objects (but note, not traits) inheriting the DelayedInit marker trait will have their initialization code rewritten as follows: code becomes delayedInit(code).

Initialization code comprises all statements and all value definitions that are executed during initialization.

Example:

trait Helper extends DelayedInit {
  def delayedInit(body: => Unit) = {
    println("dummy text, printed before initialization of C")
    body // evaluates the initialization code of C
  }
}

class C extends Helper {
  println("this is the initialization code of C")
}

object Test extends App {
  val c = new C
}

Should result in the following being printed:

dummy text, printed before initialization of C
this is the initialization code of C
See also:

"Delayed Initialization" subsection of the Scala Language Specification (section 5.1)

Deprecated
Source:
DelayedInit.scala
trait Proxy

This class implements a simple proxy that forwards all calls to the public, non-final methods defined in class Any to another object self.

This class implements a simple proxy that forwards all calls to the public, non-final methods defined in class Any to another object self. Those methods are:

def hashCode(): Int
def equals(other: Any): Boolean
def toString(): String

Note: forwarding methods in this way will most likely create an asymmetric equals method, which is not generally recommended.

Companion:
object
Deprecated
Source:
Proxy.scala
object Proxy
Companion:
class
Deprecated
Source:
Proxy.scala

This class represents uninitialized variable/value errors.

This class represents uninitialized variable/value errors.

Deprecated
[Since version 2.12.7]
Source:
UninitializedError.scala

Types

type & = [X0, X1] =>> X0 & X1

The intersection of two types.

type ::[+A] = ::[A]
type Either[+A, +B] = Either[A, B]

A tuple of 0 elements

A tuple of 0 elements

Source:
Tuple.scala
type Equiv[T] = Equiv[T]
opaque type IArray[+T]
type IndexedSeq[+A] = IndexedSeq[A]
type Integral[T] = Integral[T]
type Iterable[+A] = Iterable[A]
type Iterator[+A] = Iterator[A]
type LazyList[+A] = LazyList[A]
type Left[+A, +B] = Left[A, B]
type List[+A] = List[A]
type Numeric[T] = Numeric[T]
type Ordered[T] = Ordered[T]
type Ordering[T] = Ordering[T]
type Right[+A, +B] = Right[A, B]
type Seq[+A] = Seq[A]
type Vector[+A] = Vector[A]
type | = [X0, X1] =>> X0 | X1

The union of two types.

Deprecated types

Deprecated
Source:
package.scala
type Stream[+A] = Stream[A]
Deprecated
Source:
package.scala
type Traversable[+A] = Iterable[A]
Deprecated
Source:
package.scala
Deprecated
Source:
package.scala

Value members

Concrete fields

val +:: +:.type
val :+: :+.type
val ::: ::.type
val BigInt: BigInt.type
val Either: Either.type
val Equiv: Equiv.type
val Left: Left.type
val List: List.type
val Nil: Nil.type
val Numeric: Numeric.type
val Ordered: Ordered.type
val Range: Range.type
val Right: Right.type
val Seq: Seq.type
val Vector: Vector.type

Deprecated fields

val Stream: Stream.type
Deprecated
Source:
package.scala
Deprecated
Source:
package.scala