A trait which can be used to avoid code duplication when defining extension
methods that should be applicable both to existing Scala collections (i.e.,
types extending Iterable
) as well as other (potentially user-defined)
types that could be converted to a Scala collection type. This trait
makes it possible to treat Scala collections and types that can be implicitly
converted to a collection type uniformly. For example, one can provide
extension methods that work both on collection types and on String
s (String
s
do not extend Iterable
, but can be converted to Iterable
)
IsIterable
provides three members:
1. type member A
, which represents the element type of the target Iterable[A]
1. type member C
, which represents the type returned by transformation operations that preserve the collection’s elements type
1. method apply
, which provides a way to convert between the type we wish to add extension methods to, Repr
, and IterableOps[A, Iterable, C]
.
Usage
One must provide IsIterable
as an implicit parameter type of an implicit
conversion. Its usage is shown below. Our objective in the following example
is to provide a generic extension method mapReduce
to any type that extends
or can be converted to Iterable
. In our example, this includes
String
.
import scala.collection.{Iterable, IterableOps}
import scala.collection.generic.IsIterable
class ExtensionMethods[Repr, I <: IsIterable[Repr]](coll: Repr, it: I) {
def mapReduce[B](mapper: it.A => B)(reducer: (B, B) => B): B = {
val iter = it(coll).iterator
var res = mapper(iter.next())
while (iter.hasNext)
res = reducer(res, mapper(iter.next()))
res
}
}
implicit def withExtensions[Repr](coll: Repr)(implicit it: IsIterable[Repr]): ExtensionMethods[Repr, it.type] =
new ExtensionMethods(coll, it)
// See it in action!
List(1, 2, 3).mapReduce(_ * 2)(_ + _) // res0: Int = 12
"Yeah, well, you know, that's just, like, your opinion, man.".mapReduce(x => 1)(_ + _) // res1: Int = 59
Here, we begin by creating a class ExtensionMethods
which contains our
mapReduce
extension method.
Note that ExtensionMethods
takes a constructor argument coll
of type Repr
, where
Repr
represents (typically) the collection type, and an argument it
of a subtype of IsIterable[Repr]
.
The body of the method starts by converting the coll
argument to an IterableOps
in order to
call the iterator
method on it.
The remaining of the implementation is straightforward.
The withExtensions
implicit conversion makes the mapReduce
operation available
on any type Repr
for which it exists an implicit IsIterable[Repr]
instance.
Note how we keep track of the precise type of the implicit it
argument by using the
it.type
singleton type, rather than the wider IsIterable[Repr]
type. We do that
so that the information carried by the type members A
and C
of the it
argument
is not lost.
When the mapReduce
method is called on some type of which it is not
a member, implicit search is triggered. Because implicit conversion
withExtensions
is generic, it will be applied as long as an implicit
value of type IsIterable[Repr]
can be found. Given that the
IsIterable
companion object contains implicit members that return values of type
IsIterable
, this requirement is typically satisfied, and the chain
of interactions described in the previous paragraph is set into action.
(See the IsIterable
companion object, which contains a precise
specification of the available implicits.)
Note: Currently, it's not possible to combine the implicit conversion and the class with the extension methods into an implicit class due to limitations of type inference.
Implementing IsIterable
for New Types
One must simply provide an implicit value of type IsIterable
specific to the new type, or an implicit conversion which returns an
instance of IsIterable
specific to the new type.
Below is an example of an implementation of the IsIterable
trait
where the Repr
type is Range
.
implicit val rangeRepr: IsIterable[Range] { type A = Int; type C = IndexedSeq[Int] } =
new IsIterable[Range] {
type A = Int
type C = IndexedSeq[Int]
def apply(coll: Range): IterableOps[Int, IndexedSeq, IndexedSeq[Int]] = coll
}
(Note that in practice the IsIterable[Range]
instance is already provided by
the standard library, and it is defined as an IsSeq[Range]
instance)
- Companion
- object
- Source
- IsIterable.scala
Type members
Types
The type of elements we can traverse over (e.g.
The type of elements we can traverse over (e.g. Int
).
- Source
- IsIterableOnce.scala
The type returned by transformation operations that preserve the same elements type (e.g.
The type returned by transformation operations that preserve the same elements
type (e.g. filter
, take
).
In practice, this type is often Repr
itself, excepted in the case
of SeqView[A]
(and other View[A]
subclasses), where it is “only” View[A]
.
- Source
- IsIterable.scala
Inherited types
The type of elements we can traverse over (e.g.
The type of elements we can traverse over (e.g. Int
).
- Inherited from
- IsIterableOnce
- Source
- IsIterableOnce.scala
Value members
Abstract methods
A conversion from the representation type Repr
to a IterableOnce[A]
.
A conversion from the representation type Repr
to a IterableOnce[A]
.
- Source
- IsIterableOnce.scala
A conversion from the type Repr
to IterableOps[A, Iterable, C]
A conversion from the type Repr
to IterableOps[A, Iterable, C]
- Source
- IsIterable.scala
Deprecated fields
- Deprecated
- Source
- IsIterableOnce.scala
- Deprecated
- Source
- IsIterable.scala