# 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?

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Thanks for asking this question. I was looking at the Slick documentation and I was baffled by what "lifting" meant. – Roberto Aug 2 '13 at 17:40

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]
``````
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It might be worth mentioning that "lifting a method to a function" is often referred to as eta-expansion. – Ben James Jul 31 '13 at 9:03
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]`. – 846846846 Jul 31 '13 at 9:24
Thanks Ben, hcoopz. I've modified answer – oxbow_lakes Jul 31 '13 at 10:38
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! – Dmitry Bespalov Feb 13 '15 at 19:51

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
``````
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This is the "lifting into a functor" which oxbow_lakes describes. – Ben James Jul 31 '13 at 9:02
@BenJames True indeed. To my defence: oxbow_lakes' answer wasn't there yet when I started to write mine. – Malte Schwerhoff Jul 31 '13 at 12:06

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.

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