I don't understand what "lifting" is. Should I first understand monads before understanding what a "lift" is? (I'm completely ignorant about monads, too :) Or can someone explain it to me with simple words?

Lifting is more of a design pattern than a mathematical concept (although I expect someone around here will now refute me by showing how lifts are a category or something).

Typically you have some data type with a parameter. Something like

``````data Foo a = Foo { ...stuff here ...}
``````

Suppose you find that a lot of uses of `Foo` take numeric types (`Int`, `Double` etc) and you keep having to write code that unwraps these numbers, adds or multiplies them, and then wraps them back up. You can short-circuit this by writing the unwrap-and-wrap code once. This function is traditionally called a "lift" because it looks like this:

``````liftFoo2 :: (a -> b -> c) -> Foo a -> Foo b -> Foo c
``````

In other words you have a function which takes a two-argument function (such as the `(+)` operator) and turns it into the equivalent function for Foos.

So now you can write

``````addFoo = liftFoo2 (+)
``````

You can of course have `liftFoo3`, `liftFoo4` and so on. However this is often not necessary.

``````liftFoo1 :: (a -> b) -> Foo a -> Foo b
``````

But that is exactly the same as `fmap`. So rather than `liftFoo1` you would write

``````instance Functor Foo where
fmap foo = ...
``````

If you really want complete regularity you can then say

``````liftFoo1 = fmap
``````

If you can make `Foo` into a functor, perhaps you can make it an applicative functor. In fact, if you can write `liftFoo2` then the applicative instance looks like this:

``````import Control.Applicative

instance Applicative Foo where
pure x = Foo \$ ...   -- Wrap 'x' inside a Foo.
(<*>) = liftFoo2 (\$)
``````

The `(<*>)` operator for Foo has the type

``````(<*>) :: Foo (a -> b) -> Foo a -> Foo b
``````

It applies the wrapped function to the wrapped value. So if you can implement `liftFoo2` then you can write this in terms of it. Or you can implement it directly and not bother with `liftFoo2`, because the `Control.Applicative` module includes

``````liftA2 :: Applicative f => (a -> b -> c) -> f a -> f b -> f c
``````

and likewise there are `liftA` and `liftA3`. But you don't actually use them very often because there is another operator

``````(<\$>) = fmap
``````

This lets you write:

``````result = myFunction <\$> arg1 <*> arg2 <*> arg3 <*> arg4
``````

The term `myFunction <\$> arg1` returns a new function wrapped in Foo. This in turn can be applied to the next argument using `(<*>)`, and so on. So now instead of having a lift function for every arity, you just have a daisy chain of applicatives.

• It's probably worth reminding that lifts should respect the standard laws `lift id == id` and `lift (f . g) == (lift f) . (lift g)`. – Carlos Scheidegger Aug 12 '13 at 15:58
• Lifts are indeed "a category or something". Carlos has just listed the Functor laws, where `id` and `.` are the identity arrow and arrow composition of some category, respectively. Usually when speaking of Haskell, the category in question is "Hask", whose arrows are Haskell functions (in other words, `id` and `.` refer to the Haskell functions you know and love). – Dan Burton Aug 12 '13 at 21:39
• This should read `instance Functor Foo`, not `instance Foo Functor`, right? I'd edit myself but I'm not 100% sure. – amalloy Mar 15 '14 at 19:21
• So, lifting = Applicative functor ? – jhegedus Sep 15 '15 at 20:35
• Lifting without an Applicative is = Functor. I mean you have 2 choices : Functor or Applicative Functor. The first lifts single parameter functions the second multi parameter functions. Pretty much that's it. Right? It's not rocket science :) it just sounds like it. Thanks for the great answer btw! – jhegedus Sep 16 '15 at 12:31

Paul's and yairchu's are both good explanations.

I'd like to add that the function being lifted can have an arbitrary number of arguments and that they don't have to be of the same type. For example, you could also define a liftFoo1:

``````liftFoo1 :: (a -> b) -> Foo a -> Foo b
``````

In general, the lifting of functions that take 1 argument is captured in the type class `Functor`, and the lifting operation is called `fmap`:

``````fmap :: Functor f => (a -> b) -> f a -> f b
``````

Note the similarity with `liftFoo1`'s type. In fact, if you have `liftFoo1`, you can make `Foo` an instance of `Functor`:

``````instance Functor Foo where
fmap = liftFoo1
``````

Furthermore, the generalization of lifting to an arbitrary number of arguments is called applicative style. Don't bother diving into this until you grasp the lifting of functions with a fixed number of arguments. But when you do, Learn you a Haskell has a good chapter on this. The Typeclassopedia is another good document that describes Functor and Applicative (as well as other type classes; scroll down to the right chapter in that document).

Hope this helps!

``````> replicate 3 'a'
"aaa"
> :t replicate
replicate :: Int -> a -> [a]
> :t liftA2 replicate
liftA2 replicate :: (Applicative f) => f Int -> f a -> f [a]
> (liftA2 replicate) [1,2,3] ['a','b','c']
["a","b","c","aa","bb","cc","aaa","bbb","ccc"]
> :t liftA2
liftA2 :: (Applicative f) => (a -> b -> c) -> (f a -> f b -> f c)
``````

`liftA2` transforms a function of plain types to a function of these types wrapped in an `Applicative`, such as lists, `IO`, etc.

Another common lift is `lift` from `Control.Monad.Trans`. It transforms a monadic action of one monad to an action of a transformed monad.

In general, lifts "lift" a function/action into a "wrapped" type.

The best way to understand this, and monads etc and to understand why they are useful, is probably to code and use it. If there's anything you coded previously that you suspect can benefit from this (ie this will make that code shorter etc), just try it out and you'll easily grasp the concept.

Lifting is a concept which allows you to transform a function into a corresponding function within another (usually more general) setting

• Yeah, but that page begins "We usually start with a (covariant) functor...". Not exactly newbie friendly. – Paul Johnson Mar 7 '10 at 10:33
• But "functor" is linked, so the newbie can just click that to see what a Functor is. Admittedly, the linked page is not so good. I need to get an account and fix that. – jrockway Mar 8 '10 at 6:22
• It's a problem I've seen on other functional programming sites; each concept is explained in terms of other (unfamiliar) concepts until the newbie goes full circle (and round the bend). Must be something to do with liking recursion. – DNA Jul 5 '12 at 21:58
• @DNA Now, wait - explain recursion to me.... – BMeph Aug 12 '13 at 19:01
• Vote for this link. Lift makes connections between one world and another world. – eccstartup Aug 13 '13 at 3:31

According to this shiny tutorial, a functor is some container (like `Maybe<a>`, `List<a>` or `Tree<a>` that can store elements of some another type, `a`). I have used Java generics notation, `<a>`, for element type `a` and think of the elements as berries on the tree `Tree<a>`. There is a function `fmap`, which takes an element conversion function, `a->b` and container `functor<a>`. It applies `a->b` to every element of the container effectively converting it into `functor<b>`. When only first argument is supplied, `a->b`, `fmap` waits for the `functor<a>`. That is, supplying `a->b` alone turns this element-level function into the function `functor<a> -> functor<b>` that operates over containers. This is called lifting of the function. Because the container is also called a functor, the Functors rather than Monads are a prerequisite for the lifting. Monads are sort of "parallel" to lifting. Both rely on the Functor notion and do `f<a> -> f<b>`. The difference is that lifting uses `a->b` for the conversion whereas Monad requires the user to define `a -> f<b>`.

• I gave you a mark down, because "a functor is some container" is troll-flavored flame-bait. Example: functions from some `r` to a type (let's use `c` for variety), are Functors. They do not "contain" any `c`'s. In this instance, fmap is function composition, taking an `a -> b` function and an `r -> a` one, to give you a new, `r -> b` function. Still no containers.Also, if I could, I'd mark it down again for the final sentence. – BMeph Aug 12 '13 at 18:45
• Also, `fmap` is a function, and doesn't "wait" for anything; The "container" being a Functor is the whole point of lifting. Also, Monads are, if anything, a dual idea to lifting: a Monad lets you use something that has been lifted some positive number of times, as if it had only been lifted once - this is better known as flattening. – BMeph Aug 12 '13 at 19:00
• @BMeph `To wait`, `to expect`, `to anticipate` are the synonyms. By saying "function waits" I meant "function anticipates". – Val Mar 18 '14 at 12:24
• @BMeph I would say that instead of thinking of a function as a counterexample to the idea that functors are containers, you should think of function's sane functor instance as a counterexample to the idea that functions aren't containers. A function is a mapping from a domain to a codomain, the domain being the cross product of all of the parameters, the codomain being the output type of the function. In the same way a list is a mapping from the Naturals to the inner type of the list (domain -> codomain). They become even more similar if you memoize the function or don't keep the list. – semicolon Apr 29 '16 at 20:09
• @BMeph one of the only reason lists are thought of as more like a container is that in many languages they can be mutated, whereas traditionally functions cannot. But in Haskell even that isn't a fair statement as neither can be mutated, and both can be copy-mutated: `b = 5 : a` and `f 0 = 55` `f n = g n`, both involve pseudo-mutating the "container". Also the fact that lists are typically stored completely in memory whereas functions are typically stored as a calculation. But memoizing / monorphic lists that aren't stored between calls both break the crap out of that idea. – semicolon Apr 29 '16 at 20:12