Can anybody provide some details on <:<
operator in scala.
I think:
if(apple <:< fruit) //checks if apple is a subclass of fruit.
Are there any other explanations? I see many definitions in the scala source file.
The <:<
type is defined in Predef.scala along with the related types =:=
and <%<
as follows:
// used, for example, in the encoding of generalized constraints
// we need a new type constructor `<:<` and evidence `conforms`, as
// reusing `Function2` and `identity` leads to ambiguities (any2stringadd is inferred)
// 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 (for lower-bounds, use: `U <: T`)
// in part contributed by Jason Zaugg
sealed abstract class <:<[-From, +To] extends (From => To)
implicit def conforms[A]: A <:< A = new (A <:< A) {def apply(x: A) = x} // not in the <:< companion object because it is also intended to subsume identity (which is no longer implicit)
This uses the Scala feature that a generic type op[T1, T2]
can be written T1 op T2
. This can be used, as noted by aioobe, to provide an evidence parameter for methods that only apply to some instances of a generic type (the example given is the toMap
method that can only be used on a Traversable
of Tuple2
). As noted in the comment, this generalizes a normal generic type constraint to allow it to refer to any in-scope abstract type/type parameter. Using this (implicit ev : T1 <:< T2
) has the advantage over simply using an evidence parameter like (implicit ev: T1 => T2
) in that the latter can lead to unintended in-scope implicit values being used for the conversion.
I'm sure I'd seen some discussion on this on one of the Scala mailing lists, but can't find it at the moment.
ev: T1 <:< T2
asserts that T1
is a subtype of T2
. An implicit parameter ev: T1 =:= T2
asserts that they are the same type. See article.gmane.org/gmane.comp.lang.scala.user/18879 for an example of the latter.
May 7, 2010 at 15:30
<:<
is not an operator - it is an identifier and is therefore one of:
In this case, <:<
appears twice in the library, once in Predef
as a class and once as a method on Manifest
.
For the method on Manifest
, it checks whether the type represented by this manifest is a subtype of that represented by the manifest argument.
For the type in Predef
, this is relatively new and I am also slightly confused about it because it seems to be part of a triumvirate of identical declarations!
class <%<[-From, +To] extends (From) ⇒ To
class <:<[-From, +To] extends (From) ⇒ To
class =:=[From, To] extends (From) ⇒ To
Predef
are generalised type constraints. This mailing list thread goes over some of it: old.nabble.com/…
Apr 9, 2010 at 11:08
A => B
and <:<[A, B]
have the same variance annotations. I've realized what's going on now and it's in the implicit declarations conforms
etc as you say
Apr 9, 2010 at 16:09
=:=
and the one object is like this =:=[A,A]
or A =:= A
and there is no way one can construct another object of the type =:=
. These facts combined tells me that L =:= R
means type L
is exactly same as R
. In other words =:=
acts as a template to prove two types are equal. Hope this is not too convoluted. If it is, please ask and I will clarify to the best of my ability :)
Aug 3, 2015 at 8:17
I asked around, and this is the explanation I got:
<:<
is typically used as an evidence parameter. For example in TraversableOnce
, toMap
is declared as def toMap[T, U](implicit ev: A <:< (T, U)): immutable.Map[T, U]
. This expresses the constraint that the toMap
method only works if the traversable contains 2-tuples. flatten
is another example. <:<
is used to express the constraint that you can only flatten a traversable of traversables.
Actually, it checks if the class represented by the Manifest
apple is a subclass of the class represented by the manifest fruit.
For instance:
manifest[java.util.List[String]] <:< manifest[java.util.ArrayList[String]] == false
manifest[java.util.ArrayList[String]] <:< manifest[java.util.List[String]] == true
Copy from scala.Predef.scala:
// Type Constraints --------------------------------------------------------------
// used, for example, in the encoding of generalized constraints
// we need a new type constructor `<:<` and evidence `conforms`, as
// reusing `Function2` and `identity` leads to ambiguities (any2stringadd is inferred)
// 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 (for lower-bounds, use: `U <: T`)
// in part contributed by Jason Zaugg
sealed abstract class <:<[-From, +To] extends (From => To)
implicit def conforms[A]: A <:< A = new (A <:< A) {def apply(x: A) = x}
To better understand the implementation.
sealed abstract class <:<[-From, +To] extends (From => To)
implicit def conforms[A]: A <:< A = new (A <:< A) {def apply(x: A) = x}
I tried to devise a simpler implementation. The following did not work.
sealed class <:<[-From <: To, +To]
implicit def conforms[A <: B, B]: A <:< B = new (A <:< B)
At least because it won't type check in all valid use cases.
case class L[+A]( elem: A )
{
def contains[B](x: B)(implicit ev: A <:< B) = elem == x
}
error: type arguments [A,B] do not conform to class <:<'s
type parameter bounds [-From <: To,+To]
def contains[B](x: B)(implicit ev: A <:< B) = elem == x
^
Hmm... I can't seem to find "<:<" anywhere as well, but "<:" denotes subtyping. From http://jim-mcbeath.blogspot.com/2008/09/scala-syntax-primer.html#types :
List[T] forSome { type T <: Component }
In the above example, we are saying T is some type which is a subtype of Component.
From the sources we have the following explanation:
/**
* 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`.
*
* @note we need a new type constructor `<:<` and evidence `conforms`,
* as reusing `Function1` and `identity` leads to ambiguities in
* case of type errors (`any2stringadd` is inferred)
*
* 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 part contributed by Jason Zaugg.
*/
@implicitNotFound(msg = "Cannot prove that ${From} <:< ${To}.")
sealed abstract class <:<[-From, +To] extends (From => To) with Serializable
private[this] final val singleton_<:< = new <:<[Any,Any] { def apply(x: Any): Any = x }
// The dollar prefix is to dodge accidental shadowing of this method
// by a user-defined method of the same name (SI-7788).
// The collections rely on this method.
implicit def $conforms[A]: A <:< A = singleton_<:<.asInstanceOf[A <:< A]
@deprecated("Use `implicitly[T <:< U]` or `identity` instead.", "2.11.0")
def conforms[A]: A <:< A = $conforms[A]
/** An instance of `A =:= B` witnesses that the types `A` and `B` are equal.
*
* @see `<:<` for expressing subtyping constraints
*/
@implicitNotFound(msg = "Cannot prove that ${From} =:= ${To}.")
sealed abstract class =:=[From, To] extends (From => To) with Serializable
private[this] final val singleton_=:= = new =:=[Any,Any] { def apply(x: Any): Any = x }
object =:= {
implicit def tpEquals[A]: A =:= A = singleton_=:=.asInstanceOf[A =:= A]
}
Manifest
or the class defined inPredef
?