# What is "lifting" in Scala?

Sometimes when I read articles in the Scala ecosystem I read the term "lifting" / "lifted". Unfortunately, it is not explained what that exactly means. I did some research, and it seems that lifting has something to do with functional values or something like that, but I was not able to find a text that explains what lifting actually is about in a beginner friendly way.

There is additional confusion through the Lift framework which has lifting in its name, but it doesn't help answer the question.

What is "lifting" in Scala?

There are a few usages:

## PartialFunction

Remember a `PartialFunction[A, B]` is a function defined for some subset of the domain `A` (as specified by the `isDefinedAt` method). You can "lift" a `PartialFunction[A, B]` into a `Function[A, Option[B]]`. That is, a function defined over the whole of `A` but whose values are of type `Option[B]`

This is done by the explicit invocation of the method `lift` on `PartialFunction`.

``````scala> val pf: PartialFunction[Int, Boolean] = { case i if i > 0 => i % 2 == 0}
pf: PartialFunction[Int,Boolean] = <function1>

scala> pf.lift
res1: Int => Option[Boolean] = <function1>

scala> res1(-1)
res2: Option[Boolean] = None

scala> res1(1)
res3: Option[Boolean] = Some(false)
``````

## Methods

You can "lift" a method invocation into a function. This is called eta-expansion (thanks to @Ben James for this). So for example:

``````scala> def times2(i: Int) = i * 2
times2: (i: Int)Int
``````

We lift a method into a function by applying the underscore

``````scala> val f = times2 _
f: Int => Int = <function1>

scala> f(4)
res0: Int = 8
``````

Note the fundamental difference between methods and functions. `res0` is an instance (i.e. it is a value) of the (function) type `(Int => Int)`

## Functors

A functor (as defined by scalaz) is some "container" (I use the term extremely loosely), `F` such that, if we have an `F[A]` and a function `A => B`, then we can get our hands on an `F[B]` (think, for example, `F = List` and the `map` method)

We can encode this property as follows:

``````trait Functor[F[_]] {
def map[A, B](fa: F[A])(f: A => B): F[B]
}
``````

This is isomorphic to being able to "lift" the function `A => B` into the domain of the functor. That is:

``````def lift[F[_]: Functor, A, B](f: A => B): F[A] => F[B]
``````

That is, if `F` is a functor, and we have a function `A => B`, we have a function `F[A] => F[B]`. You might try and implement the `lift` method - it's pretty trivial.

As *hcoopz* says below (and I've just realized that this would have saved me from writing a ton of unnecessary code), the term "lift" also has a meaning within **Monad Transformers**. Recall that a monad transformers are a way of "stacking" monads on top of each other (monads do not compose).

So for example, suppose you have a function which returns an `IO[Stream[A]]`. This can be converted to the monad transformer `StreamT[IO, A]`. Now you may wish to "lift" some other value an `IO[B]` perhaps to that it is also a `StreamT`. You could either write this:

``````StreamT.fromStream(iob map (b => Stream(b)))
``````

Or this:

``````iob.liftM[StreamT]
``````

this begs the question: why do I want to convert an `IO[B]` into a `StreamT[IO, B]`?. The answer would be "to take advantage of composition possibilities". Let's say you have a function `f: (A, B) => C`

``````lazy val f: (A, B) => C = ???
val cs =
for {
a <- as                //as is a StreamT[IO, A]
b <- bs.liftM[StreamT] //bs was just an IO[B]
}
yield f(a, b)

cs.toStream //is a Stream[IO[C]], cs was a StreamT[IO, C]
``````
• Delving further into scalaz, lifting also comes up in relation to monad transformers. If I have a `MonadTrans` instance `T` for `M` and a `Monad` instance for `N`, then `T.liftM` can be used to lift a value of type `N[A]` to a value of type `M[N, A]`. Commented Jul 31, 2013 at 9:24
• Perfect! Just one more reason to say: Scala - the best. Which could be lifted to Martin Odersky & Co - the best. I even would to use `liftM` for that, but didn't manage understand how to do that properly. Guys, you're rock! Commented Feb 13, 2015 at 19:51
• In Methods section ...res0 is an instance (i.e. it is a value) of the (function) type (Int => Int)... Shouldn't `f` be an instance, not `res0`? Commented Jan 8, 2018 at 21:13

Note any collection that extends `PartialFunction[Int, A]` (as pointed out by oxbow_lakes) may be lifted; thus for instance

``````Seq(1,2,3).lift
Int => Option[Int] = <function1>
``````

which turns a partial function into a total function where values not defined in the collection are mapped onto `None`,

``````Seq(1,2,3).lift(2)
Option[Int] = Some(3)

Seq(1,2,3).lift(22)
Option[Int] = None
``````

Moreover,

``````Seq(1,2,3).lift(2).getOrElse(-1)
Int = 3

Seq(1,2,3).lift(22).getOrElse(-1)
Int = -1
``````

This shows a neat approach to avoid index out of bounds exceptions.

Another usage of lifting that I've come across in papers (not necessarily Scala-related ones) is overloading a function from `f: A -> B` with `f: List[A] -> List[B]` (or sets, multisets, ...). This is often used to simplify formalisations because it then doesn't matter whether `f` is applied to an individual element or to multiple elements.

``````f: List[A] -> List[B]
f(xs) = f(xs(1)), f(xs(2)), ..., f(xs(n))
``````

or

``````f: Set[A] -> Set[B]
f(xs) = \bigcup_{i = 1}^n f(xs(i))
``````

or imperatively, e.g.,

``````f: List[A] -> List[B]
f(xs) = xs map f
``````
• This is the "lifting into a functor" which oxbow_lakes describes. Commented Jul 31, 2013 at 9:02
• @BenJames True indeed. To my defence: oxbow_lakes' answer wasn't there yet when I started to write mine. Commented Jul 31, 2013 at 12:06

There is also unlifting, which is the inverse process to lifting.

If lifting is defined as

turning a partial function `PartialFunction[A, B]` into a total function `A => Option[B]`

then unlifting is

turning a total function `A => Option[B]` into a partial function `PartialFunction[A, B]`

Scala standard library defines `Function.unlift` as

``````def unlift[T, R](f: (T) ⇒ Option[R]): PartialFunction[T, R]
``````

For example, play-json library provides unlift to help with construction of JSON serialisers:

``````import play.api.libs.json._
import play.api.libs.functional.syntax._

case class Location(lat: Double, long: Double)

implicit val locationWrites: Writes[Location] = (
(JsPath \ "lat").write[Double] and
(JsPath \ "long").write[Double]
)(unlift(Location.unapply))
``````