=:=

@implicitNotFound(msg = "Cannot prove that ${From} =:= ${To}.")
sealed abstract class =:=[From, To] extends From <:< To with Serializable

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
class From <:< To
trait From => To
class Object
trait Matchable
class Any

Value members

Abstract methods

override def substituteBoth[F[_, _]](ftf: F[To, From]): F[From, To]
Definition Classes
Source:
typeConstraints.scala

Concrete methods

def andThen[C](r: To =:= C): From =:= C

If From = To and To = C, then From = C (equality is transitive)

If From = To and To = C, then From = C (equality is transitive)

Source:
typeConstraints.scala
override def apply(f: From): To

Coerce a From into a To.

Coerce a From into a To. This is guaranteed to be the identity function.

This method is often called implicitly as an implicit A =:= B doubles as an implicit view A => B.

Definition Classes
Source:
typeConstraints.scala
def compose[C](r: C =:= From): C =:= To

If From = To and C = From, then C = To (equality is transitive)

If From = To and C = From, then C = To (equality is transitive)

Source:
typeConstraints.scala
def flip: To =:= From

If From = To then To = From (equality is symmetric)

If From = To then To = From (equality is symmetric)

Source:
typeConstraints.scala
override def liftCo[F[_]]: F[From] =:= F[To]
Definition Classes
Source:
typeConstraints.scala
override def liftContra[F[_]]: F[To] =:= F[From]

Lift this evidence over the type constructor F, but flipped.

Lift this evidence over the type constructor F, but flipped.

Definition Classes
Source:
typeConstraints.scala
override def substituteCo[F[_]](ff: F[From]): F[To]
Definition Classes
Source:
typeConstraints.scala
override def substituteContra[F[_]](ft: F[To]): F[From]
Definition Classes
Source:
typeConstraints.scala

Inherited methods

def andThen[C](r: To <:< C): From <:< C

If From <: To and To <: C, then From <: C (subtyping is transitive)

If From <: To and To <: C, then From <: C (subtyping is transitive)

Inherited from:
<:<
Source:
typeConstraints.scala
override def andThen[C](r: To => C): From => C
Definition Classes
Inherited from:
<:<
Source:
typeConstraints.scala
def compose[C](r: C <:< From): C <:< To

If From <: To and C <: From, then C <: To (subtyping is transitive)

If From <: To and C <: From, then C <: To (subtyping is transitive)

Inherited from:
<:<
Source:
typeConstraints.scala
override def compose[C](r: C => From): C => To
Definition Classes
Inherited from:
<:<
Source:
typeConstraints.scala
override def toString(): String
Definition Classes
Inherited from:
Function1
Source:
Function1.scala