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One way that has been suggested to deal with double definitions of overloaded methods is to replace overloading with pattern matching:

object Bar {
   def foo(xs: Any*) = xs foreach { 
      case _:String => println("str")
      case _:Int => println("int")
      case _ => throw new UglyRuntimeException()

This approach requires that we surrender static type checking on the arguments to foo. It would be much nicer to be able to write

object Bar {
   def foo(xs: (String or Int)*) = xs foreach {
      case _: String => println("str")
      case _: Int => println("int")

I can get close with Either, but it gets ugly fast with more than two types:

type or[L,R] = Either[L,R]

implicit def l2Or[L,R](l: L): L or R = Left(l)
implicit def r2Or[L,R](r: R): L or R = Right(r)

object Bar {
   def foo(xs: (String or Int)*) = xs foreach {
      case Left(l) => println("str")
      case Right(r) => println("int")

It looks like a general (elegant, efficient) solution would require defining Either3, Either4, .... Does anyone know of an alternate solution to achieve the same end? To my knowledge, Scala does not have built-in "type disjunction". Also, are the implicit conversions defined above lurking in the standard library somewhere so that I can just import them?

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12 Answers

up vote 52 down vote accepted

Well, in the specific case of Any*, this trick below won't work, as it will not accept mixed types. However, since mixed types wouldn't work with overloading either, this may be what you want.

First, declare a class with the types you wish to accept as below:

class StringOrInt[T]
object StringOrInt {
  implicit object IntWitness extends StringOrInt[Int]
  implicit object StringWitness extends StringOrInt[String]

Next, declare foo like this:

object Bar {
  def foo[T: StringOrInt](x: T) = x match {
    case _: String => println("str")
    case _: Int => println("int")

And that's it. You can call foo(5) or foo("abc"), and it will work, but try foo(true) and it will fail. This could be side-stepped by the client code by creating a StringOrInt[Boolean], unless, as noted by Randall below, you make StringOrInt a sealed class.

It works because T: StringOrInt means there's an implicit parameter of type StringOrInt[T], and because Scala looks inside companion objects of a type to see if there are implicits there to make code asking for that type work.

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If class StringOrInt[T] is made sealed, the "leak" you referred to ("Of course, this could be side-stepped by the client code by creating a StringOrInt[Boolean]") is plugged, at least if StringOrInt resides in a file of its own. Then the witness objects must be defined in the same souce as StringOrInt. –  Randall Schulz Aug 18 '10 at 3:34
I tried generalizing this solution somewhat (posted as an answer below). The main drawback compared to the Either approach seems to be that we lose a lot of compiler support for checking the match. –  Aaron Novstrup Aug 18 '10 at 16:53
nice trick! However, even with the sealed class, you can still circumvent it in client code either by defining an implicit val b = new StringOrInt[Boolean] in scope with foo, or by calling explicitly foo(2.9)(new StringOrInt[Double]). I think you need to make the class abstract as well. –  Paolo Falabella Nov 14 '11 at 8:59
Yes; it would probably be better to use trait StringOrInt ... –  Mechanical snail Jul 22 '12 at 21:32
Seems like this is a typeclass, so while you can create a context where it works, StringOrInt is not a type per se, and you cannot create List[StringOrInt]... correct me if I'm wrong. –  Vlad Patryshev Mar 2 '13 at 0:19
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Miles Sabin describes a very nice way to get union type in his recent blog post Unboxed union types in Scala via the Curry-Howard isomorphism:

He first defines negation of types as

type ¬[A] = A => Nothing

using De Morgan's law this allows him to define union types

type ∨[T, U] = ¬[¬[T] with ¬[U]]

With the following auxiliary constructs

type ¬¬[A] = ¬[¬[A]]
type |∨|[T, U] = { type λ[X] = ¬¬[X] <:< (T ∨ U) }

you can write union types as follows:

def size[T : (Int |∨| String)#λ](t : T) = t match {
    case i : Int => i
    case s : String => s.length
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Thanks for passing that along. Absolutely brilliant! –  Aaron Novstrup Jun 10 '11 at 22:20
That is one of the most awesome things I've seen. –  Submonoid Nov 23 '11 at 10:30
Still trying to figure out how to make this work in a vararg context, where individual arguments may be of different "concrete" types. –  Vlad Patryshev Mar 2 '13 at 0:25
Here is my extended implementation of Miles' idea: github.com/GenslerAppsPod/scalavro/blob/master/util/src/main/… -- with examples: github.com/GenslerAppsPod/scalavro/blob/master/util/src/test/… –  Connor Doyle Aug 21 '13 at 19:40
The above comment should be an answer on its own. It is just an implementation of Miles's idea, but wrapped up nicely in a package on Maven Central, and without all those unicode symbols that might (?) pose a problem for something in a build process somewhere. –  Jim Pivarski Aug 23 '13 at 15:01
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Here is the Rex Kerr way to encode union types. Straight and simple!

scala> def f[A](a: A)(implicit ev: (Int with String) <:< A) = a match {
     |   case i: Int => i + 1
     |   case s: String => s.length
     | }
f: [A](a: A)(implicit ev: <:<[Int with String,A])Int

scala> f(3)
res0: Int = 4

scala> f("hello")
res1: Int = 5

scala> f(9.2)
<console>:9: error: Cannot prove that Int with String <:< Double.

Source: Comment #27 under this excellent blog post by Miles Sabin which provides another way of encoding union types in Scala.

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Unfortunately, this encoding can be defeated: scala> f(9.2: AnyVal) passes the typechecker. –  Kipton Barros Aug 14 '11 at 6:20
@Kipton: That's sad. Does Miles Sabin's encoding also suffer from this problem? –  missingfaktor Aug 14 '11 at 17:35
No, that one works. –  Kipton Barros Aug 14 '11 at 18:37
There is a slightly simpler version of Miles' code; since he's actually using the reverse implication of the contravariant parameter of the function, not a strict "not", you can use trait Contra[-A] {} in place of all the functions to nothing. So you get stuff like type Union[A,B] = { type Check[Z] = Contra[Contra[Z]] <:< Contra[Contra[A] with Contra[B]] } used like def f[T: Union[Int, String]#Check](t: T) = t match { case i: Int => i; case s: String => s.length } (without fancy unicode). –  Rex Kerr Aug 23 '11 at 23:00
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It's possible to generalize Daniel's solution as follows:

sealed trait Or[A, B]

object Or {
   implicit def a2Or[A,B](a: A) = new Or[A, B] {}
   implicit def b2Or[A,B](b: B) = new Or[A, B] {}

object Bar {
   def foo[T <% String Or Int](x: T) = x match {
     case _: String => println("str")
     case _: Int => println("int")

The main drawbacks of this approach are

  • As Daniel pointed out, it does not handle collections/varargs with mixed types
  • The compiler does not issue a warning if the match is not exhaustive
  • The compiler does not issue an error if the match includes an impossible case
  • Like the Either approach, further generalization would require defining analogous Or3, Or4, etc. traits. Of course, defining such traits would be much simpler than defining the corresponding Either classes.


Mitch Blevins demonstrates a very similar approach and shows how to generalize it to more than two types, dubbing it the "stuttering or".

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A type class solution is probably the nicest way to go here, using implicits. This is similar to the monoid approach mentioned in the Odersky/Spoon/Venners book:

abstract class NameOf[T] {
  def get : String

implicit object NameOfStr extends NameOf[String] {
  def get = "str"

implicit object NameOfInt extends NameOf[Int] {
 def get = "int"

def printNameOf[T](t:T)(implicit name : NameOf[T]) = println(name.get)

If you then run this in the REPL:

scala> printNameOf(1)

scala> printNameOf("sss")

scala> printNameOf(2.0f)
<console>:10: error: could not find implicit value for parameter nameOf: NameOf[

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I could be wrong, but I don't think this is what the OP was looking for. OP was asking about a data type which could represent a disjoint union of types, and then do case analysis on it at runtime to see what the actual type turned out to be. Type classes won't solve this problem, as they're a purely compile-time construct. –  pelotom Aug 20 '10 at 22:27
The real question being asked was how to expose different behaviour for different types, but without overloading. Without knowledge of type classes (and perhaps some exposure to C/C++), a union type appears to be the only solution. Scala's pre-existing Either type tends to reinforce this belief. Using type classes via Scala's implicits is a better solution to the underlying problem, but it's a relatively new concept and still not widely known, which is why the OP didn't even know to consider them as a possible alternative to a union type. –  Kevin Wright Aug 23 '10 at 11:46
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You might take a look at MetaScala, which has something called OneOf. I get the impression that this doesn't work well with match statements but that you can simulate matching using higher-order functions. Take a look at this snippet, for instance, but note that the "simulated matching" part is commented out, maybe because it doesn't quite work yet.

Now for some editorializing: I don't think there's anything egregious about defining Either3, Either4, etc. as you describe. This is essentially dual to the standard 22 tuple types built in to Scala. It'd certainly be nice if Scala had built-in disjunctive types, and perhaps some nice syntax for them like {x, y, z}.

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There is also this hack:

implicit val x: Int = 0
def foo(a: List[Int])(implicit ignore: Int) { }

implicit val y = ""
def foo(a: List[String])(implicit ignore: String) { }


See Working around type erasure ambiguities (Scala).

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See stackoverflow.com/questions/3422336/…. There's actually an easier hack: just add (implicit e: DummyImplicit) to one of the type signatures. –  Aaron Novstrup Aug 20 '10 at 19:17
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I am thinking that the first class disjoint type is a sealed supertype, with the alternate subtypes, and implicit conversions to/from the desired types of the disjunction to these alternative subtypes.

I assume this addresses comments 33 - 36 of Miles Sabin's solution, so the first class type that can be employed at the use site, but I didn't test it.

sealed trait IntOrString
case class IntOfIntOrString( v:Int ) extends IntOrString
case class StringOfIntOrString( v:String ) extends IntOrString
implicit def IntToIntOfIntOrString( v:Int ) = new IntOfIntOrString(v)
implicit def StringToStringOfIntOrString( v:String ) = new StringOfIntOrString(v)

object Int {
   def unapply( t : IntOrString ) : Option[Int] = t match {
      case v : IntOfIntOrString => Some( v.v )
      case _ => None

object String {
   def unapply( t : IntOrString ) : Option[String] = t match {
      case v : StringOfIntOrString => Some( v.v )
      case _ => None

def size( t : IntOrString ) = t match {
    case Int(i) => i
    case String(s) => s.length

scala> size("test")
res0: Int = 4
scala> size(2)
res1: Int = 2

One problem is Scala will not employ in case matching context, an implicit conversion from IntOfIntOrString to Int (and StringOfIntOrString to String), so must define extractors and use case Int(i) instead of case i : Int.

ADD: I responded to Miles Sabin at his blog as follows. Perhaps there are several improvements over Either:

  1. It extends to more than 2 types, without any additional noise at the use or definition site.
  2. Arguments are boxed implicitly, e.g. don't need size(Left(2)) or size(Right("test")).
  3. The syntax of the pattern matching is implicitly unboxed.
  4. The boxing and unboxing may be optimized away by the JVM hotspot.
  5. The syntax could be the one adopted by a future first class union type, so migration could perhaps be seamless? Perhaps for the union type name, it would be better to use V instead of Or, e.g. IntVString, `Int |v| String`, `Int or String`, or my favorite `Int|String`?

UPDATE: Logical negation of the disjunction for the above pattern follows, and I added an alternative (and probably more useful) pattern at Miles Sabin's blog.

sealed trait `Int or String`
sealed trait `not an Int or String`
sealed trait `Int|String`[T,E]
case class `IntOf(Int|String)`( v:Int ) extends `Int|String`[Int,`Int or String`]
case class `StringOf(Int|String)`( v:String ) extends `Int|String`[String,`Int or String`]
case class `NotAn(Int|String)`[T]( v:T ) extends `Int|String`[T,`not an Int or String`]
implicit def `IntTo(IntOf(Int|String))`( v:Int ) = new `IntOf(Int|String)`(v)
implicit def `StringTo(StringOf(Int|String))`( v:String ) = new `StringOf(Int|String)`(v)
implicit def `AnyTo(NotAn(Int|String))`[T]( v:T ) = new `NotAn(Int|String)`[T](v)
def disjunction[T,E](x: `Int|String`[T,E])(implicit ev: E =:= `Int or String`) = x
def negationOfDisjunction[T,E](x: `Int|String`[T,E])(implicit ev: E =:= `not an Int or String`) = x

scala> disjunction(5)
res0: Int|String[Int,Int or String] = IntOf(Int|String)(5)

scala> disjunction("")
res1: Int|String[String,Int or String] = StringOf(Int|String)()

scala> disjunction(5.0)
error: could not find implicit value for parameter ev: =:=[not an Int or String,Int or String]

scala> negationOfDisjunction(5)
error: could not find implicit value for parameter ev: =:=[Int or String,not an Int or String]

scala> negationOfDisjunction("")
error: could not find implicit value for parameter ev: =:=[Int or String,not an Int or String]
scala> negationOfDisjunction(5.0)
res5: Int|String[Double,not an Int or String] = NotAn(Int|String)(5.0)

ANOTHER UPDATE: Regarding comments 23 and 35 of Mile Sabin's solution, here is a way to declare a union type at the use site. Note it is unboxed after the first level, i.e. it has the advantage being extensible to any number of types in the disjunction, whereas Either needs nested boxing and the paradigm in my prior comment 41 was not extensible. In other words, a D[Int ∨ String] is assignable to (i.e. is a subtype of) a D[Int ∨ String ∨ Double].

type ¬[A] = (() => A) => A
type ∨[T, U] = ¬[T] with ¬[U]
class D[-A](v: A) {
  def get[T](f: (() => T)) = v match {
    case x : ¬[T] => x(f)
def size(t: D[Int ∨ String]) = t match {
  case x: D[¬[Int]] => x.get( () => 0 )
  case x: D[¬[String]] => x.get( () => "" )
  case x: D[¬[Double]] => x.get( () => 0.0 )
implicit def neg[A](x: A) = new D[¬[A]]( (f: (() => A)) => x )

scala> size(5)
res0: Any = 5

scala> size("")
error: type mismatch;
 found   : java.lang.String("")
 required: D[?[Int,String]]

scala> size("hi" : D[¬[String]])
res2: Any = hi

scala> size(5.0 : D[¬[Double]])
error: type mismatch;
 found   : D[(() => Double) => Double]
 required: D[?[Int,String]]
       size(5.0 : D[?[Double]])

Apparently the Scala compiler has three bugs.

  1. It will not choose the correct implicit function for any type after the first type in the destination disjunction.
  2. It doesn't exclude the D[¬[Double]] case from the match.


scala> class D[-A](v: A) {
  def get[T](f: (() => T))(implicit e: A <:< ¬[T]) = v match {
    case x : ¬[T] => x(f)
error: contravariant type A occurs in covariant position in
       type <:<[A,(() => T) => T] of value e
         def get[T](f: (() => T))(implicit e: A <:< ?[T]) = v match {

The get method isn't constrained properly on input type, because the compiler won't allow A in the covariant position. One might argue that is a bug because all we want is evidence, we don't ever access the evidence in the function. And I made the choice not to test for case _ in the get method, so I wouldn't have to unbox an Option in the match in size().

March 05, 2012: The prior update needs an improvement. Miles Sabin's solution worked correctly with subtyping.

type ¬[A] = A => Nothing
type ∨[T, U] = ¬[T] with ¬[U]
class Super
class Sub extends Super

scala> implicitly[(Super ∨ String) <:< ¬[Super]]
res0: <:<[?[Super,String],(Super) => Nothing] = 

scala> implicitly[(Super ∨ String) <:< ¬[Sub]]
res2: <:<[?[Super,String],(Sub) => Nothing] = 

scala> implicitly[(Super ∨ String) <:< ¬[Any]]
error: could not find implicit value for parameter
       e: <:<[?[Super,String],(Any) => Nothing]
       implicitly[(Super ? String) <:< ?[Any]]

My prior update's proposal (for near first-class union type) broke subtyping.

 scala> implicitly[D[¬[Sub]] <:< D[(Super ∨ String)]]
error: could not find implicit value for parameter
       e: <:<[D[(() => Sub) => Sub],D[?[Super,String]]]
       implicitly[D[?[Sub]] <:< D[(Super ? String)]]

The problem is that A in (() => A) => A appears in both the covariant (return type) and contravariant (function input, or in this case a return value of function which is a function input) positions, thus substitutions can only be invariant.

Note that A => Nothing is necessary only because we want A in the contravariant position, so that supertypes of A are not subtypes of D[¬[A]] nor D[¬[A] with ¬[U]] (see also). Since we only need double contravariance, we can achieve equivalent to Miles' solution even if we can discard the ¬ and .

trait D[-A]

scala> implicitly[D[D[Super]] <:< D[D[Super] with D[String]]]
res0: <:<[D[D[Super]],D[D[Super] with D[String]]] = 

scala> implicitly[D[D[Sub]] <:< D[D[Super] with D[String]]]
res1: <:<[D[D[Sub]],D[D[Super] with D[String]]] = 

scala> implicitly[D[D[Any]] <:< D[D[Super] with D[String]]]
error: could not find implicit value for parameter
       e: <:<[D[D[Any]],D[D[Super] with D[String]]]
       implicitly[D[D[Any]] <:< D[D[Super] with D[String]]]

So the complete fix is.

class D[-A] (v: A) {
  def get[T <: A] = v match {
    case x: T => x

implicit def neg[A](x: A) = new D[D[A]]( new D[A](x) )

def size(t: D[D[Int] with D[String]]) = t match {
  case x: D[D[Int]] => x.get[D[Int]].get[Int]
  case x: D[D[String]] => x.get[D[String]].get[String]
  case x: D[D[Double]] => x.get[D[Double]].get[Double]

Note the prior 2 bugs in Scala remain, but the 3rd one is avoided as T is now constrained to be subtype of A.

We can confirm the subtyping works.

def size(t: D[D[Super] with D[String]]) = t match {
  case x: D[D[Super]] => x.get[D[Super]].get[Super]
  case x: D[D[String]] => x.get[D[String]].get[String]

scala> size( new Super )
res7: Any = Super@1272e52

scala> size( new Sub )
res8: Any = Sub@1d941d7

I have been thinking that first-class intersection types are very important, both for the reasons Ceylon has them, and because instead of subsuming to Any which means unboxing with a match on expected types can generate a runtime error, the unboxing of a (heterogeneous collection containing a) disjunction can be type checked (Scala has to fix the bugs I noted). Unions are more straightforward than the complexity of using the experimental HList of metascala for heterogeneous collections.

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The #3 item above is not a bug in the Scala compiler. Note I originally had not numbered it as a bug, then carelessly made an edit today and did so (forgetting my original reason for not stating it was a bug). I didn't edit the post again, because I am at the 7 edits limit. –  Shelby Moore III Mar 5 '12 at 19:28
The #1 bug above can be avoided with a different formulation of the size function. –  Shelby Moore III May 3 '12 at 14:19
The #2 item is not a bug. Scala can't fully express a union type. The linked document provides another version of the code, so that size no longer accepts D[Any] as input. –  Shelby Moore III May 4 '12 at 9:27
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If you can use Scala 2.8, take a look into type classes. It does something very similar to what you are asking, but you will have to create implicit functions. Ghosh gives an example of a type safe JSON serializer.

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I have sort of stumbled on a relatively clean implementation of n-ary union types by combining the notion of type lists with a simplification of Miles Sabin's work in this area, which someone mentions in another answer.

Given type ¬[-A] which is contravariant on A, by definition given A <: B we can write ¬[B] <: ¬[A], inverting the ordering of types.

Given types A, B, and X, we want to express X <: A || X <: B. Applying contravariance, we get ¬[A] <: ¬[X] || ¬[B] <: ¬[X]. This can in turn be expressed as ¬[A] with ¬[B] <: ¬[X] in which one of A or B must be a supertype of X or X itself (think about function arguments).

object Union {
  import scala.language.higherKinds

  sealed trait ¬[-A]

  sealed trait TSet {
    type Compound[A]
    type Map[F[_]] <: TSet

  sealed trait ∅ extends TSet {
    type Compound[A] = A
    type Map[F[_]] = ∅ 

  // Note that this type is left-associative for the sake of concision.
  sealed trait ∨[T <: TSet, H] extends TSet {
    // Given a type of the form `∅ ∨ A ∨ B ∨ ...` and parameter `X`, we want to produce the type
    // `¬[A] with ¬[B] with ... <:< ¬[X]`.
    type Member[X] = T#Map[¬]#Compound[¬[H]] <:< ¬[X]

    // This could be generalized as a fold, but for concision we leave it as is.
    type Compound[A] = T#Compound[H with A]

    type Map[F[_]] = T#Map[F] ∨ F[H]

  def foo[A : (∅ ∨ String ∨ Int ∨ List[Int])#Member](a: A): String = a match {
    case s: String => "String"
    case i: Int => "Int"
    case l: List[_] => "List[Int]"

  foo(List(1, 2, 3))
  foo(42d) // error
  foo[Any](???) // error

I did spend some time trying to combine this idea with an upper bound on member types as seen in the TLists of harrah/up, however the implementation of Map with type bounds has thus far proved challenging.

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There is another way which is slightly easier to understand if you do not grok Curry-Howard:

type v[A,B] = Either[Option[A], Option[B]]

private def L[A,B](a: A): v[A,B] = Left(Some(a))
private def R[A,B](b: B): v[A,B] = Right(Some(b))  
// TODO: for more use scala macro to generate this for up to 22 types?
implicit def a2[A,B](a: A): v[A,B] = L(a)
implicit def b2[A,B](b: B): v[A,B] = R(b)
implicit def a3[A,B,C](a: A): v[v[A,B],C] = L(a2(a))
implicit def b3[A,B,C](b: B): v[v[A,B],C] = L(b2(b))
implicit def a4[A,B,C,D](a: A): v[v[v[A,B],C],D] = L(a3(a))
implicit def b4[A,B,C,D](b: B): v[v[v[A,B],C],D] = L(b3(b))    
implicit def a5[A,B,C,D,E](a: A): v[v[v[v[A,B],C],D],E] = L(a4(a))
implicit def b5[A,B,C,D,E](b: B): v[v[v[v[A,B],C],D],E] = L(b4(b))

type JsonPrimtives = (String v Int v Double)
type ValidJsonPrimitive[A] = A => JsonPrimtives

def test[A : ValidJsonPrimitive)(x: A): A = x 

// test(true)   // does not compile

I use similar technique in dijon

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Well, that's all very clever, but I'm pretty sure you know already that the answers to your leading questions are various varieties of "No". Scala handles overloading differently and, it must be admitted, somewhat less elegantly than you describe. Some of that's due to Java interoperability, some of that is due to not wanting to hit edged cases of the type inferencing algorithm, and some of that's due to it simply not being Haskell.

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While I've been using Scala for a while, I'm neither as knowledgeable nor as smart as you seem to think. In this example, I can see how a library could provide the solution. It makes sense to then wonder whether such a library exists (or some alternative). –  Aaron Novstrup Aug 18 '10 at 2:05
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