Functors, Applicative Functors and Monoids
Haskell's combination of purity, higher order functions, parameterized algebraic data types, and typeclasses allows us to implement polymorphism on a much higher level than possible in other languages. We don't have to think about types belonging to a big hierarchy of types. Instead, we think about what the types can act like and then connect them with the appropriate typeclasses. An Int can act like a lot of things. It can act like an equatable thing, like an ordered thing, like an enumerable thing, etc.
Typeclasses are open, which means that we can define our own data type, think about what it can act like and connect it with the typeclasses that define its behaviors. Because of that and because of Haskell's great type system that allows us to know a lot about a function just by knowing its type declaration, we can define typeclasses that define behavior that's very general and abstract. We've met typeclasses that define operations for seeing if two things are equal or comparing two things by some ordering. Those are very abstract and elegant behaviors, but we just don't think of them as anything very special because we've been dealing with them for most of our lives. We recently met functors, which are basically things that can be mapped over. That's an example of a useful and yet still pretty abstract property that typeclasses can describe. In this chapter, we'll take a closer look at functors, along with slightly stronger and more useful versions of functors called applicative functors. We'll also take a look at monoids, which are sort of like socks.
Functors redux
We've already talked about functors in their own little section. If you haven't read it yet, you should probably give it a glance right now, or maybe later when you have more time. Or you can just pretend you read it.
Still, here's a quick refresher: Functors are things that can be mapped over, like lists, Maybes, trees, and such. In Haskell, they're described by the typeclass Functor, which has only one typeclass method, namely fmap, which has a type of fmap :: (a -> b) -> f a -> f b. It says: give me a function that takes an a and returns a b and a box with an a (or several of them) inside it and I'll give you a box with a b (or several of them) inside it. It kind of applies the function to the element inside the box.
If we want to make a type constructor an instance of Functor, it has to have a kind of * -> *, which means that it has to take exactly one concrete type as a type parameter. For example, Maybe can be made an instance because it takes one type parameter to produce a concrete type, like Maybe Int or Maybe String. If a type constructor takes two parameters, like Either, we have to partially apply the type constructor until it only takes one type parameter. So we can't write instance Functor Either where, but we can write instance Functor (Either a) where and then if we imagine that fmap is only for Either a, it would have a type declaration of fmap :: (b -> c) -> Either a b -> Either a c. As you can see, the Either a part is fixed, because Either a takes only one type parameter, whereas just Either takes two so fmap :: (b -> c) -> Either b -> Either c wouldn't really make sense.
We've learned by now how a lot of types (well, type constructors really) are instances of Functor, like [], Maybe, Either a and a Tree type that we made on our own. We saw how we can map functions over them for great good. In this section, we'll take a look at two more instances of functor, namely IO and (->) r.
If some value has a type of, say, IO String, that means that it's an I/O action that, when performed, will go out into the real world and get some string for us, which it will yield as a result. We can use <- in do syntax to bind that result to a name. We mentioned that I/O actions are like boxes with little feet that go out and fetch some value from the outside world for us. We can inspect what they fetched, but after inspecting, we have to wrap the value back in IO. By thinking about this box with little feet analogy, we can see how IO acts like a functor.
Let's see how IO is an instance of Functor. When we fmap a function over an I/O action, we want to get back an I/O action that does the same thing, but has our function applied over its result value.
instance Functor IO where fmap f action = do result <- action return (f result)
The result of mapping something over an I/O action will be an I/O action, so right off the bat we use do syntax to glue two actions and make a new one. In the implementation for fmap, we make a new I/O action that first performs the original I/O action and calls its result result. Then, we do return (f result). return is, as you know, a function that makes an I/O action that doesn't do anything but only presents something as its result. The action that a do block produces will always have the result value of its last action. That's why we use return to make an I/O action that doesn't really do anything, it just presents f result as the result of the new I/O action.
We can play around with it to gain some intuition. It's pretty simple really. Check out this piece of code:
main = do line <- getLine let line' = reverse line putStrLn $ "You said " ++ line' ++ " backwards!" putStrLn $ "Yes, you really said" ++ line' ++ " backwards!"
The user is prompted for a line and we give it back to the user, only reversed. Here's how to rewrite this by using fmap:
main = do line <- fmap reverse getLine putStrLn $ "You said " ++ line ++ " backwards!" putStrLn $ "Yes, you really said" ++ line ++ " backwards!"
Just like when we fmap reverse over Just "blah" to get Just "halb", we can fmap reverse over getLine. getLine is an I/O action that has a type of IO String and mapping reverse over it gives us an I/O action that will go out into the real world and get a line and then apply reverse to its result. Like we can apply a function to something that's inside a Maybe box, we can apply a function to what's inside an IO box, only it has to go out into the real world to get something. Then when we bind it to a name by using <-, the name will reflect the result that already has reverse applied to it.
The I/O action fmap (++"!") getLine behaves just like getLine, only that its result always has "!" appended to it!
If we look at what fmap's type would be if it were limited to IO, it would be fmap :: (a -> b) -> IO a -> IO b. fmap takes a function and an I/O action and returns a new I/O action that's like the old one, except that the function is applied to its contained result.
If you ever find yourself binding the result of an I/O action to a name, only to apply a function to that and call that something else, consider using fmap, because it looks prettier. If you want to apply multiple transformations to some data inside a functor, you can declare your own function at the top level, make a lambda function or ideally, use function composition:
import Data.Char import Data.List main = do line <- fmap (intersperse '-' . reverse . map toUpper) getLine putStrLn line
$ runhaskell fmapping_io.hs hello there E-R-E-H-T- -O-L-L-E-H
As you probably know, intersperse '-' . reverse . map toUpper is a function that takes a string, maps toUpper over it, the applies reverse to that result and then applies intersperse '-' to that result. It's like writing (\xs -> intersperse '-' (reverse (map toUpper xs))), only prettier.
Another instance of Functor that we've been dealing with all along but didn't know was a Functor is (->) r. You're probably slightly confused now, since what the heck does (->) r mean? The function type r -> a can be rewritten as (->) r a, much like we can write 2 + 3 as (+) 2 3. When we look at it as (->) r a, we can see (->) in a slighty different light, because we see that it's just a type constructor that takes two type parameters, just like Either. But remember, we said that a type constructor has to take exactly one type parameter so that it can be made an instance of Functor. That's why we can't make (->) an instance of Functor, but if we partially apply it to (->) r, it doesn't pose any problems. If the syntax allowed for type constructors to be partially applied with sections (like we can partially apply + by doing (2+), which is the same as (+) 2), you could write (->) r as (r ->). How are functions functors? Well, let's take a look at the implementation, which lies in Control.Monad.Instances
instance Functor ((->) r) where fmap f g = (\x -> f (g x))
If the syntax allowed for it, it could have been written as
instance Functor (r ->) where fmap f g = (\x -> f (g x))
But it doesn't, so we have to write it in the former fashion.
First of all, let's think about fmap's type. It's fmap :: (a -> b) -> f a -> f b. Now what we'll do is mentally replace all the f's, which are the role that our functor instance plays, with (->) r's. We'll do that to see how fmap should behave for this particular instance. We get fmap :: (a -> b) -> ((->) r a) -> ((->) r b). Now what we can do is write the (->) r a and (-> r b) types as infix r -> a and r -> b, like we normally do with functions. What we get now is fmap :: (a -> b) -> (r -> a) -> (r -> b).
Hmmm OK. Mapping one function over a function has to produce a function, just like mapping a function over a Maybe has to produce a Maybe and mapping a function over a list has to produce a list. What does the type fmap :: (a -> b) -> (r -> a) -> (r -> b) for this instance tell us? Well, we see that it takes a function from a to b and a function from r to a and returns a function from r to b. Does this remind you of anything? Yes! Function composition! We pipe the output of r -> a into the input of a -> b to get a function r -> b, which is exactly what function composition is about. If you look at how the instance is defined above, you'll see that it's just function composition. Another way to write this instance would be:
instance Functor ((->) r) where fmap = (.)
This makes the revelation that using fmap over functions is just composition sort of obvious. Do :m + Control.Monad.Instances, since that's where the instance is defined and then try playing with mapping over functions.
ghci> :t fmap (*3) (+100) fmap (*3) (+100) :: (Num a) => a -> a ghci> fmap (*3) (+100) 1 303 ghci> (*3) `fmap` (+100) $ 1 303 ghci> (*3) . (+100) $ 1 303 ghci> fmap (show . (*3)) (*100) 1 "300"
We can call fmap as an infix function so that the resemblance to . is clear. In the second input line, we're mapping (*3) over (+100), which results in a function that will take an input, call (+100) on that and then call (*3) on that result. We call that function with 1.
How does the box analogy hold here? Well, if you stretch it, it holds. When we use fmap (+3) over Just 3, it's easy to imagine the Maybe as a box that has some contents on which we apply the function (+3). But what about when we're doing fmap (*3) (+100)? Well, you can think of the function (+100) as a box that contains its eventual result. Sort of like how an I/O action can be thought of as a box that will go out into the real world and fetch some result. Using fmap (*3) on (+100) will create another function that acts like (+100), only before producing a result, (*3) will be applied to that result. Now we can see how fmap acts just like . for functions.
The fact that fmap is function composition when used on functions isn't so terribly useful right now, but at least it's very interesting. It also bends our minds a bit and let us see how things that act more like computations than boxes (IO and (->) r) can be functors. The function being mapped over a computation results in the same computation but the result of that computation is modified with the function.
Before we go on to the rules that fmap should follow, let's think about the type of fmap once more. Its type is fmap :: (a -> b) -> f a -> f b. We're missing the class constraint (Functor f) =>, but we left it out here for brevity, because we're talking about functors anyway so we know what the f stands for. When we first learned about curried functions, we said that all Haskell functions actually take one parameter. A function a -> b -> c actually takes just one parameter of type a and then returns a function b -> c, which takes one parameter and returns a c. That's how if we call a function with too few parameters (i.e. partially apply it), we get back a function that takes the number of parameters that we left out (if we're thinking about functions as taking several parameters again). So a -> b -> c can be written as a -> (b -> c), to make the currying more apparent.
In the same vein, if we write fmap :: (a -> b) -> (f a -> f b), we can think of fmap not as a function that takes one function and a functor and returns a functor, but as a function that takes a function and returns a new function that's just like the old one, only it takes a functor as a parameter and returns a functor as the result. It takes an a -> b function and returns a function f a -> f b. This is called lifting a function. Let's play around with that idea by using GHCI's :t command:
ghci> :t fmap (*2) fmap (*2) :: (Num a, Functor f) => f a -> f a ghci> :t fmap (replicate 3) fmap (replicate 3) :: (Functor f) => f a -> f [a]
The expression fmap (*2) is a function that takes a functor f over numbers and returns a functor over numbers. That functor can be a list, a Maybe , an Either String, whatever. The expression fmap (replicate 3) will take a functor over any type and return a functor over a list of elements of that type.
This is even more apparent if we partially apply, say, fmap (++"!") and then bind it to a name in GHCI.
You can think of fmap as either a function that takes a function and a functor and then maps that function over the functor, or you can think of it as a function that takes a function and lifts that function so that it operates on functors. Both views are correct and in Haskell, equivalent.
The type fmap (replicate 3) :: (Functor f) => f a -> f [a] means that the function will work on any functor. What exactly it will do depends on which functor we use it on. If we use fmap (replicate 3) on a list, the list's implementation for fmap will be chosen, which is just map. If we use it on a Maybe a, it'll apply replicate 3 to the value inside the Just, or if it's Nothing, then it stays Nothing.
ghci> fmap (replicate 3) [1,2,3,4] [[1,1,1],[2,2,2],[3,3,3],[4,4,4]] ghci> fmap (replicate 3) (Just 4) Just [4,4,4] ghci> fmap (replicate 3) (Right "blah") Right ["blah","blah","blah"] ghci> fmap (replicate 3) Nothing Nothing ghci> fmap (replicate 3) (Left "foo") Left "foo"
Next up, we're going to look at the functor laws. In order for something to be a functor, it should satisfy some laws. All functors are expected to exhibit certain kinds of functor-like properties and behaviors. They should reliably behave as things that can be mapped over. Calling fmap on a functor should just map a function over the functor, nothing more. This behavior is described in the functor laws. There are two of them that all instances of Functor should abide by. They aren't enforced by Haskell automatically, so you have to test them out yourself.
The first functor law states that if we map the id function over a functor, the functor that we get back should be the same as the original functor. If we write that a bit more formally, it means that fmap id = id. So essentially, this says that if we do fmap id over a functor, it should be the same as just calling id on the functor. Remember, id is the identity function, which just returns its parameter unmodified. It can also be written as \x -> x. If we view the functor as something that can be mapped over, the fmap id = id law seems kind of trivial or obvious.
Let's see if this law holds for a few values of functors.
ghci> fmap id (Just 3) Just 3 ghci> id (Just 3) Just 3 ghci> fmap id [1..5] [1,2,3,4,5] ghci> id [1..5] [1,2,3,4,5] ghci> fmap id [] [] ghci> fmap id Nothing Nothing
If we look at the implementation of fmap for, say, Maybe, we can figure out why the first functor law holds.
instance Functor Maybe where fmap f (Just x) = Just (f x) fmap f Nothing = Nothing
We imagine that id plays the role of the f parameter in the implementation. We see that if wee fmap id over Just x, the result will be Just (id x), and because id just returns its parameter, we can deduce that Just (id x) equals Just x. So now we know that if we map id over a Maybe value with a Just value constructor, we get that same value back.
Seeing that mapping id over a Nothing value returns the same value is trivial. So from these two equations in the implementation for fmap, we see that the law fmap id = id holds.
The second law says that composing two functions and then mapping the resulting function over a functor should be the same as first mapping one function over the functor and then mapping the other one. Formally written, that means that fmap (f . g) = fmap f . fmap g. Or to write it in another way, for any functor F, the following should hold: fmap (f . g) F = fmap f (fmap g F).
If we can show that some type obeys both functor laws, we can rely on it having the same fundamental behaviors as other functors when it comes to mapping. We can know that when we use fmap on it, there won't be anything other than mapping going on behind the scenes and that it will act like a thing that can be mapped over, i.e. a functor. You figure out how the second law holds for some type by looking at the implementation of fmap for that type and then using the method that we used to check if Maybe obeys the first law.
If you want, we can check out how the second functor law holds for Maybe. If we do fmap (f . g) over Nothing, we get Nothing, because doing a fmap with any function over Nothing returns Nothing. If we do fmap f (fmap g Nothing), we get Nothing, for the same reason. OK, seeing how the second law holds for Maybe if it's a Nothing value is pretty easy, almost trivial.
How about if it's a Just something value? Well, if we do fmap (f . g) (Just x), we see from the implementation that it's implemented as Just ((f . g) x), which is, of course, Just (f (g x)). If we do fmap f (fmap g (Just x)), we see from the implementation that fmap g (Just x) is Just (g x). Ergo, fmap f (fmap g (Just x)) equals fmap f (Just (g x)) and from the implementation we see that this equals Just (f (g x)).
If you're a bit confused by this proof, don't worry. Be sure that you understand how function composition works. Many times, you can intuitively see how these laws hold because the types act like containers or functions. You can also just try them on a bunch of different values of a type and be able to say with some certainty that a type does indeed obey the laws.
Let's take a look at a pathological example of a type constructor being an instance of the Functor typeclass but not really being a functor, because it doesn't satisfy the laws. Let's say that we have a type:
data CMaybe a = CNothing | CJust Int a deriving (Show)
The C here stands for counter. It's a data type that looks much like Maybe a, only the Just part holds two fields instead of one. The first field in the CJust value constructor will always have a type of Int, and it will be some sort of counter and the second field is of type a, which comes from the type parameter and its type will, of course, depend on the concrete type that we choose for CMaybe a. Let's play with our new type to get some intuition for it.
ghci> CNothing CNothing ghci> CJust 0 "haha" CJust 0 "haha" ghci> :t CNothing CNothing :: CMaybe a ghci> :t CJust 0 "haha" CJust 0 "haha" :: CMaybe [Char] ghci> CJust 100 [1,2,3] CJust 100 [1,2,3]
If we use the CNothing constructor, there are no fields, and if we use the CJust constructor, the first field is an integer and the second field can be any type. Let's make this an instance of Functor so that everytime we use fmap, the function gets applied to the second field, whereas the first field gets increased by 1.
instance Functor CMaybe where fmap f CNothing = CNothing fmap f (CJust counter x) = CJust (counter+1) (f x)
This is kind of like the instance implementation for Maybe, except that when we do fmap over a value that doesn't represent an empty box (a CJust value), we don't just apply the function to the contents, we also increase the counter by 1. Everything seems cool so far, we can even play with this a bit:
ghci> fmap (++"ha") (CJust 0 "ho") CJust 1 "hoha" ghci> fmap (++"he") (fmap (++"ha") (CJust 0 "ho")) CJust 2 "hohahe" ghci> fmap (++"blah") CNothing CNothing
Does this obey the functor laws? In order to see that something doesn't obey a law, it's enough to find just one counter-example.
ghci> fmap id (CJust 0 "haha") CJust 1 "haha" ghci> id (CJust 0 "haha") CJust 0 "haha"
Ah! We know that the first functor law states that if we map id over a functor, it should be the same as just calling id with the same functor, but as we've seen from this example, this is not true for our CMaybe functor. Even though it's part of the Functor typeclass, it doesn't obey the functor laws and is therefore not a functor. If someone used our CMaybe type as a functor, they would expect it to obey the functor laws like a good functor. But CMaybe fails at being a functor even though it pretends to be one, so using it as a functor might lead to some faulty code. When we use a functor, it shouldn't matter if we first compose a few functions and then map them over the functor or if we just map each function over a functor in succession. But with CMaybe, it matters, because it keeps track of how many times it's been mapped over. Not cool! If we wanted CMaybe to obey the functor laws, we'd have to make it so that the Int field stays the same when we use fmap.
At first, the functor laws might seem a bit confusing and unnecessary, but then we see that if we know that a type obeys both laws, we can make certain assumptions about how it will act. If a type obeys the functor laws, we know that calling fmap on a value of that type will only map the function over it, nothing more. This leads to code that is more abstract and extensible, because we can use laws to reason about behaviors that any functor should have and make functions that operate reliably on any functor.
All the Functor instances in the standard library obey these laws, but you can check for yourself if you don't believe me. And the next time you make a type an instance of Functor, take a minute to make sure that it obeys the functor laws. Once you've dealt with enough functors, you kind of intuitively see the properties and behaviors that they have in common and it's not hard to intuitively see if a type obeys the functor laws. But even without the intuition, you can always just go over the implementation line by line and see if the laws hold or try to find a counter-example.
We can also look at functors as things that output values in a context. For instance, Just 3 outputs the value 3 in the context that it might or not output any values at all. [1,2,3] outputs three values—1, 2, and 3, the context is that there may be multiple values or no values. The function (+3) will output a value, depending on which parameter it is given.
If you think of functors as things that output values, you can think of mapping over functors as attaching a transformation to the output of the functor that changes the value. When we do fmap (+3) [1,2,3], we attach the transformation (+3) to the output of [1,2,3], so whenever we look at a number that the list outputs, (+3) will be applied to it. Another example is mapping over functions. When we do fmap (+3) (*3), we attach the transformation (+3) to the eventual output of (*3). Looking at it this way gives us some intuition as to why using fmap on functions is just composition (fmap (+3) (*3) equals (+3) . (*3), which equals \x -> ((x*3)+3)), because we take a function like (*3) then we attach the transformation (+3) to its output. The result is still a function, only when we give it a number, it will be multiplied by three and then it will go through the attached transformation where it will be added to three. This is what happens with composition.
Applicative functors
In this section, we'll take a look at applicative functors, which are beefed up functors, represented in Haskell by the Applicative typeclass, found in the Control.Applicative module.
As you know, functions in Haskell are curried by default, which means that a function that seems to take several parameters actually takes just one parameter and returns a function that takes the next parameter and so on. If a function is of type a -> b -> c, we usually say that it takes two parameters and returns a c, but actually it takes an a and returns a function b -> c. That's why we can call a function as f x y or as (f x) y. This mechanism is what enables us to partially apply functions by just calling them with too few parameters, which results in functions that we can then pass on to other functions.
So far, when we were mapping functions over functors, we usually mapped functions that take only one parameter. But what happens when we map a function like *, which takes two parameters, over a functor? Let's take a look at a couple of concrete examples of this. If we have Just 3 and we do fmap (*) (Just 3), what do we get? From the instance implementation of Maybe for Functor, we know that if it's a Just something value, it will apply the function to the something inside the Just. Therefore, doing fmap (*) (Just 3) results in Just ((*) 3), which can also be written as Just (* 3) if we use sections. Interesting! We get a function wrapped in a Just!
ghci> :t fmap (++) (Just "hey") fmap (++) (Just "hey") :: Maybe ([Char] -> [Char]) ghci> :t fmap compare (Just 'a') fmap compare (Just 'a') :: Maybe (Char -> Ordering) ghci> :t fmap compare "A LIST OF CHARS" fmap compare "A LIST OF CHARS" :: [Char -> Ordering] ghci> :t fmap (\x y z -> x + y / z) [3,4,5,6] fmap (\x y z -> x + y / z) [3,4,5,6] :: (Fractional a) => [a -> a -> a]
If we map compare, which has a type of (Ord a) => a -> a -> Ordering over a list of characters, we get a list of functions of type Char -> Ordering, because the function compare gets partially applied with the characters in the list. It's not a list of (Ord a) => a -> Ordering function, because the first a that got applied was a Char and so the second a has to decide to be of type Char.
We see how by mapping "multi-parameter" functions over functors, we get functors that contain functions inside them. So now what can we do with them? Well for one, we can map functions that take these functions as parameters over them, because whatever is inside a functor will be given to the function that we're mapping over it as a parameter.
ghci> let a = fmap (*) [1,2,3,4] ghci> :t a a :: [Integer -> Integer] ghci> fmap (\f -> f 9) a [9,18,27,36]
But what if we have a functor value of Just (3 *) and a functor value of Just 5 and we want to take out the function from Just (3 *) and map it over Just 5? With normal functors, we're out of luck, because all they support is just mapping normal functions over existing functors. Even when we mapped \f -> f 9 over a functor that contained functions inside it, we were just mapping a normal function over it. But we can't map a function that's inside a functor over another functor with what fmap offers us. We could pattern-match against the Just constructor to get the function out of it and then map it over Just 5, but we're looking for a more general and abstract way of doing that, which works across functors.
Meet the Applicative typeclass. It lies in the Control.Applicative module and it defines two methods, pure and <*>. It doesn't provide a default implementation for any of them, so we have to define them both if we want something to be an applicative functor. The class is defined like so:
class (Functor f) => Applicative f where pure :: a -> f a (<*>) :: f (a -> b) -> f a -> f b
This simple three line class definition tells us a lot! Let's start at the first line. It starts the definition of the Applicative class and it also introduces a class constraint. It says that if we want to make a type constructor part of the Applicative typeclass, it has to be in Functor first. That's why if we know that if a type constructor is part of the Applicative typeclass, it's also in Functor, so we can use fmap on it.
The first method it defines is called pure. Its type declaration is pure :: a -> f a. f plays the role of our applicative functor instance here. Because Haskell has a very good type system and because everything a function can do is take some parameters and return some value, we can tell a lot from a type declaration and this is no exception. pure should take a value of any type and return an applicative functor with that value inside it. When we say inside it, we're using the box analogy again, even though we've seen that it doesn't always stand up to scrutiny. But the a -> f a type declaration is still pretty descriptive. We take a value and we wrap it in an applicative functor that has that value as the result inside it.
A better way of thinking about pure would be to say that it takes a value and puts it in some sort of default (or pure) context—a minimal context that still yields that value.
The <*> function is really interesting. It has a type declaration of f (a -> b) -> f a -> f b. Does this remind you of anything? Of course, fmap :: (a -> b) -> f a -> f b. It's a sort of a beefed up fmap. Whereas fmap takes a function and a functor and applies the function inside the functor, <*> takes a functor that has a function in it and another functor and sort of extracts that function from the first functor and then maps it over the second one. When I say extract, I actually sort of mean run and then extract, maybe even sequence. We'll see why soon.
Let's take a look at the Applicative instance implementation for Maybe.
instance Applicative Maybe where pure = Just Nothing <*> _ = Nothing (Just f) <*> something = fmap f something
Again, from the class definition we see that the f that plays the role of the applicative functor should take one concrete type as a parameter, so we write instance Applicative Maybe where instead of writing instance Applicative (Maybe a) where.
First off, pure. We said earlier that it's supposed to take something and wrap it in an applicative functor. We wrote pure = Just, because value constructors like Just are normal functions. We could have also written pure x = Just x.
Next up, we have the definition for <*>. We can't extract a function out of a Nothing, because it has no function inside it. So we say that if we try to extract a function from a Nothing, the result is a Nothing. If you look at the class definition for Applicative, you'll see that there's a Functor class constraint, which means that we can assume that both of <*>'s parameters are functors. If the first parameter is not a Nothing, but a Just with some function inside it, we say that we then want to map that function over the second parameter. This also takes care of the case where the second parameter is Nothing, because doing fmap with any function over a Nothing will return a Nothing.
So for Maybe, <*> extracts the function from the left value if it's a Just and maps it over the right value. If any of the parameters is Nothing, Nothing is the result.
OK cool great. Let's give this a whirl.
ghci> Just (+3) <*> Just 9 Just 12 ghci> pure (+3) <*> Just 10 Just 13 ghci> pure (+3) <*> Just 9 Just 12 ghci> Just (++"hahah") <*> Nothing Nothing ghci> Nothing <*> Just "woot" Nothing
We see how doing pure (+3) and Just (+3) is the same in this case. Use pure if you're dealing with Maybe values in an applicative context (i.e. using them with <*>), otherwise stick to Just. The first four input lines demonstrate how the function is extracted and then mapped, but in this case, they could have been achieved by just mapping unwrapped functions over functors. The last line is interesting, because we try to extract a function from a Nothing and then map it over something, which of course results in a Nothing.
With normal functors, you can just map a function over a functor and then you can't get the result out in any general way, even if the result is a partially applied function. Applicative functors, on the other hand, allow you to operate on several functors with a single function. Check out this piece of code:
ghci> pure (+) <*> Just 3 <*> Just 5 Just 8 ghci> pure (+) <*> Just 3 <*> Nothing Nothing ghci> pure (+) <*> Nothing <*> Just 5 Nothing
What's going on here? Let's take a look, step by step. <*> is left-associative, which means that pure (+) <*> Just 3 <*> Just 5 is the same as (pure (+) <*> Just 3) <*> Just 5. First, the + function is put in a functor, which is in this case a Maybe value that contains the function. So at first, we have pure (+), which is Just (+). Next, Just (+) <*> Just 3 happens. The result of this is Just (3+). This is because of partial application. Only applying 3 to the + function results in a function that takes one parameter and adds 3 to it. Finally, Just (3+) <*> Just 5 is carried out, which results in a Just 8.
Isn't this awesome?! Applicative functors and the applicative style of doing pure f <*> x <*> y <*> ... allow us to take a function that expects parameters that aren't necessarily wrapped in functors and use that function to operate on several values that are in functor contexts. The function can take as many parameters as we want, because it's always partially applied step by step between occurences of <*>.
This becomes even more handy and apparent if we consider the fact that pure f <*> x equals fmap f x. This is one of the applicative laws. We'll take a closer look at them later, but for now, we can sort of intuitively see that this is so. Think about it, it makes sense. Like we said before, pure puts a value in a default context. If we just put a function in a default context and then extract and apply it to a value inside another applicative functor, we did the same as just mapping that function over that applicative functor. Instead of writing pure f <*> x <*> y <*> ..., we can write fmap f x <*> y <*> .... This is why Control.Applicative exports a function called <$>, which is just fmap as an infix operator. Here's how it's defined:
(<$>) :: (Functor f) => (a -> b) -> f a -> f b f <$> x = fmap f x
By using <$>, the applicative style really shines, because now if we want to apply a function f between three applicative functors, we can write f <$> x <*> y <*> z. If the parameters weren't applicative functors but normal values, we'd write f x y z.
Let's take a closer look at how this works. We have a value of Just "johntra" and a value of Just "volta" and we want to join them into one String inside a Maybe functor. We do this:
ghci> (++) <$> Just "johntra" <*> Just "volta" Just "johntravolta"
Before we see how this happens, compare the above line with this:
ghci> (++) "johntra" "volta" "johntravolta"
Awesome! To use a normal function on applicative functors, just sprinkle some <$> and <*> about and the function will operate on applicatives and return an applicative. How cool is that?
Anyway, when we do (++) <$> Just "johntra" <*> Just "volta", first (++), which has a type of (++) :: [a] -> [a] -> [a] gets mapped over Just "johntra", resulting in a value that's the same as Just ("johntra"++) and has a type of Maybe ([Char] -> [Char]). Notice how the first parameter of (++) got eaten up and how the as turned into Chars. And now Just ("johntra"++) <*> Just "volta" happens, which takes the function out of the Just and maps it over Just "volta", resulting in Just "johntravolta". Had any of the two values been Nothing, the result would have also been Nothing.
So far, we've only used Maybe in our examples and you might be thinking that applicative functors are all about Maybe. There are loads of other instances of Applicative, so let's go and meet them!
Lists (actually the list type constructor, []) are applicative functors. What a suprise! Here's how [] is an instance of Applicative:
instance Applicative [] where pure x = [x] fs <*> xs = [f x | f <- fs, x <- xs]
Earlier, we said that pure takes a value and puts it in a default context. Or in other words, a minimal context that still yields that value. The minimal context for lists would be the empty list, [], but the empty list represents the lack of a value, so it can't hold in itself the value that we used pure on. That's why pure takes a value and puts it in a singleton list. Similarly, the minimal context for the Maybe applicative functor would be a Nothing, but it represents the lack of a value instead of a value, so pure is implemented as Just in the instance implementation for Maybe.
ghci> pure "Hey" :: [String] ["Hey"] ghci> pure "Hey" :: Maybe String Just "Hey"
What about <*>? If we look at what <*>'s type would be if it were limited only to lists, we get (<*>) :: [a -> b] -> [a] -> [b]. It's implemented with a list comprehension. <*> has to somehow extract the function out of its left parameter and then map it over the right parameter. But the thing here is that the left list can have zero functions, one function, or several functions inside it. The right list can also hold several values. That's why we use a list comprehension to draw from both lists. We apply every possible function from the left list to every possible value from the right list. The resulting list has every possible combination of applying a function from the left list to a value in the right one.
ghci> [(*0),(+100),(^2)] <*> [1,2,3] [0,0,0,101,102,103,1,4,9]
The left list has three functions and the right list has three values, so the resulting list will have nine elements. Every function in the left list is applied to every function in the right one. If we have a list of functions that take two parameters, we can apply those functions between two lists.
ghci> [(+),(*)] <*> [1,2] <*> [3,4] [4,5,5,6,3,4,6,8]
Because <*> is left-associative, [(+),(*)] <*> [1,2] happens first, resulting in a list that's the same as [(1+),(2+),(1*),(2*)], because every function on the left gets applied to every value on the right. Then, [(1+),(2+),(1*),(2*)] <*> [3,4] happens, which produces the final result.
Using the applicative style with lists is fun! Watch:
ghci> (++) <$> ["ha","heh","hmm"] <*> ["?","!","."] ["ha?","ha!","ha.","heh?","heh!","heh.","hmm?","hmm!","hmm."]
Again, see how we used a normal function that takes two strings between two applicative functors of strings just by inserting the appropriate applicative operators.
You can view lists as non-deterministic computations. A value like 100 or "what" can be viewed as a deterministic computation that has only one result, whereas a list like [1,2,3] can be viewed as a computation that can't decide on which result it wants to have, so it presents us with all of the possible results. So when you do something like (+) <$> [1,2,3] <*> [4,5,6], you can think of it as adding together two non-deterministic computations with +, only to produce another non-deterministic computation that's even less sure about its result.
Using the applicative style on lists is often a good replacement for list comprehensions. In the second chapter, we wanted to see all the possible products of [2,5,10] and [8,10,11], so we did this:
ghci> [ x*y | x <- [2,5,10], y <- [8,10,11]] [16,20,22,40,50,55,80,100,110]
We're just drawing from two lists and applying a function between every combination of elements. This can be done in the applicative style as well:
ghci> (*) <$> [2,5,10] <*> [8,10,11] [16,20,22,40,50,55,80,100,110]
This seems clearer to me, because it's easier to see that we're just calling * between two non-deterministic computations. If we wanted all possible products of those two lists that are more than 50, we'd just do:
ghci> filter (>50) $ (*) <$> [2,5,10] <*> [8,10,11] [55,80,100,110]
It's easy to see how pure f <*> xs equals fmap f xs with lists. pure f is just [f] and [f] <*> xs will apply every function in the left list to every value in the right one, but there's just one function in the left list, so it's like mapping.
Another instance of Applicative that we've already encountered is IO. This is how the instance is implemented:
instance Applicative IO where pure = return a <*> b = do f <- a x <- b return (f x)
Since pure is all about putting a value in a minimal context that still holds it as its result, it makes sense that pure is just return, because return does exactly that; it makes an I/O action that doesn't do anything, it just yields some value as its result, but it doesn't really do any I/O operations like printing to the terminal or reading from a file.
If <*> were specialized for IO it would have a type of (<*>) :: IO (a -> b) -> IO a -> IO b. It would take an I/O action that yields a function as its result and another I/O action and create a new I/O action from those two that, when performed, first performs the first one to get the function and then performs the second one to get the value and then it would yield that function applied to the value as its result. We used do syntax to implement it here. Remember, do syntax is about taking several I/O actions and gluing them into one, which is exactly what we do here.
With Maybe and [], we could think of <*> as simply extracting a function from its left parameter and then sort of applying it over the right one. With IO, extracting is still in the game, but now we also have a notion of sequencing, because we're taking two I/O actions and we're sequencing, or gluing, them into one. We have to extract the function from the first I/O action, but to extract a result from an I/O action, it has to be performed.
Consider this:
myAction :: IO String myAction = do a <- getLine b <- getLine return $ a ++ b
This is an I/O action that will prompt the user for two lines and yield as its result those two lines concatenated. We achieved it by gluing together two getLine I/O actions and a return, because we wanted our new glued I/O action to hold the result of a ++ b. Another way of writing this would be to use the applicative style.
myAction :: IO String myAction = (++) <$> getLine <*> getLine
What we were doing before was making an I/O action that applied a function between the results of two other I/O actions, and this is the same thing. Remember, getLine is an I/O action with the type getLine :: IO String. When we use <*> between two applicative functors, the result is an applicative functor, so this all makes sense.
If we regress to the box analogy, we can imagine getLine as a box that will go out into the real world and fetch us a string. Doing (++) <$> getLine <*> getLine makes a new, bigger box that sends those two boxes out to fetch lines from the terminal and then presents the concatenation of those two lines as its result.
The type of the expression (++) <$> getLine <*> getLine is IO String, which means that this expression is a completely normal I/O action like any other, which also holds a result value inside it, just like other I/O actions. That's why we can do stuff like:
main = do a <- (++) <$> getLine <*> getLine putStrLn $ "The two lines concatenated turn out to be: " ++ a
If you ever find yourself binding some I/O actions to names and then calling some function on them and presenting that as the result by using return, consider using the applicative style because it's arguably a bit more concise and terse.
Another instance of Applicative is (->) r, so functions. They are rarely used with the applicative style outside of code golf, but they're still interesting as applicatives, so let's take a look at how the function instance is implemented.
instance Applicative ((->) r) where pure x = (\_ -> x) f <*> g = \x -> f x (g x)
When we wrap a value into an applicative functor with pure, the result it yields always has to be that value. A minimal default context that still yields that value as a result. That's why in the function instance implementation, pure takes a value and creates a function that ignores its parameter and always returns that value. If we look at the type for pure, but specialized for the (->) r instance, it's pure :: a -> (r -> a).
ghci> (pure 3) "blah" 3
Because of currying, function application is left-associative, so we can omit the parentheses.
ghci> pure 3 "blah" 3
The instance implementation for <*> is a bit cryptic, so it's best if we just take a look at how to use functions as applicative functors in the applicative style.
ghci> :t (+) <$> (+3) <*> (*100) (+) <$> (+3) <*> (*100) :: (Num a) => a -> a ghci> (+) <$> (+3) <*> (*100) $ 5 508
Calling <*> with two applicative functors results in an applicative functor, so if we use it on two functions, we get back a function. So what goes on here? When we do (+) <$> (+3) <*> (*100), we're making a function that will use + on the results of (+3) and (*100) and return that. To demonstrate on a real example, when we did (+) <$> (+3) <*> (*100) $ 5, the 5 first got applied to (+3) and (*100), resulting in 8 and 500. Then, + gets called with 8 and 500, resulting in 508.
ghci> (\x y z -> [x,y,z]) <$> (+3) <*> (*2) <*> (/2) $ 5 [8.0,10.0,2.5]
Same here. We create a function that will call the function \x y z -> [x,y,z] with the eventual results from (+3), (*2) and (/2). The 5 gets fed to each of the three functions and then \x y z -> [x, y, z] gets called with those results.
You can think of functions as boxes that contain their eventual results, so doing k <$> f <*> g creates a function that will call k with the eventual results from f and g. When we do something like (+) <$> Just 3 <*> Just 5, we're using + on values that might or might not be there, which also results in a value that might or might not be there. When we do (+) <$> (+10) <*> (+5), we're using + on the future return values of (+10) and (+5) and the result is also something that will produce a value only when called with a parameter.
We don't often use functions as applicatives, but this is still really interesting. It's not very important that you get how the (->) r instance for Applicative works, so don't despair if you're not getting this right now. Try playing with the applicative style and functions to build up an intuition for functions as applicatives.
An instance of Applicative that we haven't encountered yet is ZipList, and it lives in Control.Applicative.
It turns out there are actually more ways for lists to be applicative functors. One way is the one we already covered, which says that calling <*> with a list of functions and a list of values results in a list which has all the possible combinations of applying functions from the left list to the values in the right list. If we do [(+3),(*2)] <*> [1,2], (+3) will be applied to both 1 and 2 and (*2) will also be applied to both 1 and 2, resulting in a list that has four elements, namely [4,5,2,4].
However, [(+3),(*2)] <*> [1,2] could also work in such a way that the first function in the left list gets applied to the first value in the right one, the second function gets applied to the second value, and so on. That would result in a list with two values, namely [4,4]. You could look at it as [1 + 3, 2 * 2].
Because one type can't have two instances for the same typeclass, the ZipList a type was introduced, which has one constructor ZipList that has just one field, and that field is a list. Here's the instance:
instance Applicative ZipList where pure x = ZipList (repeat x) ZipList fs <*> ZipList xs = ZipList (zipWith (\f x -> f x) fs xs)
<*> does just what we said. It applies the first function to the first value, the second function to the second value, etc. This is done with zipWith (\f x -> f x) fs xs. Because of how zipWith works, the resulting list will be as long as the shorter of the two lists.
pure is also interesting here. It takes a value and puts it in a list that just has that value repeating indefinitely. pure "haha" results in ZipList (["haha","haha","haha".... This might be a bit confusing since we said that pure should put a value in a minimal context that still yields that value. And you might be thinking that an infinite list of something is hardly minimal. But it makes sense with zip lists, because it has to produce the value on every position. This also satisfies the law that pure f <*> xs should equal fmap f xs. If pure 3 just returned ZipList [3], pure (*2) <*> ZipList [1,5,10] would result in ZipList [2], because the resulting list of two zipped lists has the length of the shorter of the two. If we zip a finite list with an infinite list, the length of the resulting list will always be equal to the length of the finite list.
So how do zip lists work in an applicative style? Let's see. Oh, the ZipList a type doesn't have a Show instance, so we have to use the getZipList function to extract a raw list out of a zip list.
ghci> getZipList $ (+) <$> ZipList [1,2,3] <*> ZipList [100,100,100] [101,102,103] ghci> getZipList $ (+) <$> ZipList [1,2,3] <*> ZipList [100,100..] [101,102,103] ghci> getZipList $ max <$> ZipList [1,2,3,4,5,3] <*> ZipList [5,3,1,2] [5,3,3,4] ghci> getZipList $ (,,) <$> ZipList "dog" <*> ZipList "cat" <*> ZipList "rat" [('d','c','r'),('o','a','a'),('g','t','t')]
Aside from zipWith, the standard library has functions such as zipWith3, zipWith4, all the way up to 7. zipWith takes a function that takes two parameters and zips two lists with it. zipWith3 takes a function that takes three parameters and zips three lists with it, and so on. By using zip lists with an applicative style, we don't have to have a separate zip function for each number of lists that we want to zip together. We just use the applicative style to zip together an arbitrary amount of lists with a function, and that's pretty cool.
Control.Applicative defines a function that's called liftA2, which has a type of liftA2 :: (Applicative f) => (a -> b -> c) -> f a -> f b -> f c . It's defined like this:
liftA2 :: (Applicative f) => (a -> b -> c) -> f a -> f b -> f c liftA2 f a b = f <$> a <*> b
Nothing special, it just applies a function between two applicatives, hiding the applicative style that we've become familiar with. The reason we're looking at it is because it clearly showcases why applicative functors are more powerful than just ordinary functors. With ordinary functors, we can just map functions over one functor. But with applicative functors, we can apply a function between several functors. It's also interesting to look at this function's type as (a -> b -> c) -> (f a -> f b -> f c). When we look at it like this, we can say that liftA2 takes a normal binary function and promotes it to a function that operates on two functors.
Here's an interesting concept: we can take two applicative functors and combine them into one applicative functor that has inside it the results of those two applicative functors in a list. For instance, we have Just 3 and Just 4. Let's assume that the second one has a singleton list inside it, because that's really easy to achieve:
ghci> fmap (\x -> [x]) (Just 4) Just [4]
OK, so let's say we have Just 3 and Just [4]. How do we get Just [3,4]? Easy.
ghci> liftA2 (:) (Just 3) (Just [4]) Just [3,4] ghci> (:) <$> Just 3 <*> Just [4] Just [3,4]
Remember, : is a function that takes an element and a list and returns a new list with that element at the beginning. Now that we have Just [3,4], could we combine that with Just 2 to produce Just [2,3,4]? Of course we could. It seems that we can combine any amount of applicatives into one applicative that has a list of the results of those applicatives inside it. Let's try implementing a function that takes a list of applicatives and returns an applicative that has a list as its result value. We'll call it sequenceA.
sequenceA :: (Applicative f) => [f a] -> f [a] sequenceA [] = pure [] sequenceA (x:xs) = (:) <$> x <*> sequenceA xs
Ah, recursion! First, we look at the type. It will transform a list of applicatives into an applicative with a list. From that, we can lay some groundwork for an edge condition. If we want to turn an empty list into an applicative with a list of results, well, we just put an empty list in a default context. Now comes the recursion. If we have a list with a head and a tail (remember, x is an applicative and xs is a list of them), we call sequenceA on the tail, which results in an applicative with a list. Then, we just prepend the value inside the applicative x into that applicative with a list, and that's it!
So if we do sequenceA [Just 1, Just 2], that's (:) <$> Just 1 <*> sequenceA [Just 2] . That equals (:) <$> Just 1 <*> ((:) <$> Just 2 <*> sequenceA []). Ah! We know that sequenceA [] ends up as being Just [], so this expression is now (:) <$> Just 1 <*> ((:) <$> Just 2 <*> Just []), which is (:) <$> Just 1 <*> Just [2], which is Just [1,2]!
Another way to implement sequenceA is with a fold. Remember, pretty much any function where we go over a list element by element and accumulate a result along the way can be implemented with a fold.
sequenceA :: (Applicative f) => [f a] -> f [a] sequenceA = foldr (liftA2 (:)) (pure [])
We approach the list from the right and start off with an accumulator value of pure []. We do liftA2 (:) between the accumulator and the last element of the list, which results in an applicative that has a singleton in it. Then we do liftA2 (:) with the now last element and the current accumulator and so on, until we're left with just the accumulator, which holds a list of the results of all the applicatives.
Let's give our function a whirl on some applicatives.
ghci> sequenceA [Just 3, Just 2, Just 1] Just [3,2,1] ghci> sequenceA [Just 3, Nothing, Just 1] Nothing ghci> sequenceA [(+3),(+2),(+1)] 3 [6,5,4] ghci> sequenceA [[1,2,3],[4,5,6]] [[1,4],[1,5],[1,6],[2,4],[2,5],[2,6],[3,4],[3,5],[3,6]] ghci> sequenceA [[1,2,3],[4,5,6],[3,4,4],[]] []
Ah! Pretty cool. When used on Maybe values, sequenceA creates a Maybe value with all the results inside it as a list. If one of the values was Nothing, then the result is also a Nothing. This is cool when you have a list of Maybe values and you're interested in the values only if none of them is a Nothing.
When used with functions, sequenceA takes a list of functions and returns a function that returns a list. In our example, we made a function that took a number as a parameter and applied it to each function in the list and then returned a list of results. sequenceA [(+3),(+2),(+1)] 3 will call (+3) with 3, (+2) with 3 and (+1) with 3 and present all those results as a list.
Doing (+) <$> (+3) <*> (*2) will create a function that takes a parameter, feeds it to both (+3) and (*2) and then calls + with those two results. In the same vein, it makes sense that sequenceA [(+3),(*2)] makes a function that takes a parameter and feeds it to all of the functions in the list. Instead of calling + with the results of the functions, a combination of : and pure [] is used to gather those results in a list, which is the result of that function.
Using sequenceA is cool when we have a list of functions and we want to feed the same input to all of them and then view the list of results. For instance, we have a number and we're wondering whether it satisfies all of the predicates in a list. One way to do that would be like so:
ghci> map (\f -> f 7) [(>4),(<10),odd] [True,True,True] ghci> and $ map (\f -> f 7) [(>4),(<10),odd] True
Remember, and takes a list of booleans and returns True if they're all True. Another way to achieve the same thing would be with sequenceA:
ghci> sequenceA [(>4),(<10),odd] 7 [True,True,True] ghci> and $ sequenceA [(>4),(<10),odd] 7 True
sequenceA [(>4),(<10),odd] creates a function that will take a number and feed it to all of the predicates in [(>4),(<10),odd] and return a list of booleans. It turns a list with the type (Num a) => [a -> Bool] into a function with the type (Num a) => a -> [Bool]. Pretty neat, huh?
Because lists are homogenous, all the functions in the list have to be functions of the same type, of course. You can't have a list like [ord, (+3)], because ord takes a character and returns a number, whereas (+3) takes a number and returns a number.
When used with [], sequenceA takes a list of lists and returns a list of lists. Hmm, interesting. It actually creates lists that have all possible combinations of their elements. For illustration, here's the above done with sequenceA and then done with a list comprehension:
ghci> sequenceA [[1,2,3],[4,5,6]] [[1,4],[1,5],[1,6],[2,4],[2,5],[2,6],[3,4],[3,5],[3,6]] ghci> [[x,y] | x <- [1,2,3], y <- [4,5,6]] [[1,4],[1,5],[1,6],[2,4],[2,5],[2,6],[3,4],[3,5],[3,6]] ghci> sequenceA [[1,2],[3,4]] [[1,3],[1,4],[2,3],[2,4]] ghci> [[x,y] | x <- [1,2], y <- [3,4]] [[1,3],[1,4],[2,3],[2,4]] ghci> sequenceA [[1,2],[3,4],[5,6]] [[1,3,5],[1,3,6],[1,4,5],[1,4,6],[2,3,5],[2,3,6],[2,4,5],[2,4,6]] ghci> [[x,y,z] | x <- [1,2], y <- [3,4], z <- [5,6]] [[1,3,5],[1,3,6],[1,4,5],[1,4,6],[2,3,5],[2,3,6],[2,4,5],[2,4,6]]
This might be a bit hard to grasp, but if you play with it for a while, you'll see how it works. Let's say that we're doing sequenceA [[1,2],[3,4]]. To see how this happens, let's use the sequenceA (x:xs) = (:) <$> x <*> sequenceA xs definition of sequenceA and the edge condition sequenceA [] = pure []. You don't have to follow this evaluation, but it might help you if have trouble imagining how sequenceA works on lists of lists, because it can be a bit mind-bending.
- We start off with sequenceA [[1,2],[3,4]]
- That evaluates to (:) <$> [1,2] <*> sequenceA [[3,4]]
- Evaluating the inner sequenceA further, we get (:) <$> [1,2] <*> ((:) <$> [3,4] <*> sequenceA [])
- We've reached the edge condition, so this is now (:) <$> [1,2] <*> ((:) <$> [3,4] <*> [[]])
- Now, we evaluate the (:) <$> [3,4] <*> [[]] part, which will use : with every possible value in the left list (possible values are 3 and 4) with every possible value on the right list (only possible value is []), which results in [3:[], 4:[]], which is [[3],[4]]. So now we have (:) <$> [1,2] <*> [[3],[4]]
- Now, : is used with every possible value from the left list (1 and 2) with every possible value in the right list ([3] and [4]), which results in [1:[3], 1:[4], 2:[3], 2:[4]], which is [[1,3],[1,4],[2,3],[2,4]
Doing (+) <$> [1,2] <*> [4,5,6]results in a non-deterministic computation x + y where x takes on every value from [1,2] and y takes on every value from [4,5,6]. We represent that as a list which holds all of the possible results. Similarly, when we do sequence [[1,2],[3,4],[5,6],[7,8]], the result is a non-deterministic computation [x,y,z,w], where x takes on every value from [1,2], y takes on every value from [3,4] and so on. To represent the result of that non-deterministic computation, we use a list, where each element in the list is one possible list. That's why the result is a list of lists.
When used with I/O actions, sequenceA is the same thing as sequence! It takes a list of I/O actions and returns an I/O action that will perform each of those actions and have as its result a list of the results of those I/O actions. That's because to turn an [IO a] value into an IO [a] value, to make an I/O action that yields a list of results when performed, all those I/O actions have to be sequenced so that they're then performed one after the other when evaluation is forced. You can't get the result of an I/O action without performing it.
ghci> sequenceA [getLine, getLine, getLine] heyh ho woo ["heyh","ho","woo"]
Like normal functors, applicative functors come with a few laws. The most important one is the one that we already mentioned, namely that pure f <*> x = fmap f x holds. As an exercise, you can prove this law for some of the applicative functors that we've met in this chapter.The other functor laws are:
- pure id <*> v = v
- pure (.) <*> u <*> v <*> w = u <*> (v <*> w)
- pure f <*> pure x = pure (f x)
- u <*> pure y = pure ($ y) <*> u
We won't go over them in detail right now because that would take up a lot of pages and it would probably be kind of boring, but if you're up to the task, you can take a closer look at them and see if they hold for some of the instances.
In conclusion, applicative functors aren't just interesting, they're also useful, because they allow us to combine different computations, such as I/O computations, non-deterministic computations, computations that might have failed, etc. by using the applicative style. Just by using <$> and <*> we can use normal functions to uniformly operate on any number of applicative functors and take advantage of the semantics of each one.
The newtype keyword
So far, we've learned how to make our own algebraic data types by using the data keyword. We've also learned how to give existing types synonyms with the type keyword. In this section, we'll be taking a look at how to make new types out of existing data types by using the newtype keyword and why we'd want to do that in the first place.
In the previous section, we saw that there are actually more ways for the list type to be an applicative functor. One way is to have <*> take every function out of the list that is its left parameter and apply it to every value in the list that is on the right, resulting in every possible combination of applying a function from the left list to a value in the right list.
ghci> [(+1),(*100),(*5)] <*> [1,2,3] [2,3,4,100,200,300,5,10,15]
The second way is to take the first function on the left side of <*> and apply it to the first value on the right, then take the second function from the list on the left side and apply it to the second value on the right, and so on. Ultimately, it's kind of like zipping the two lists together. But lists are already an instance of Applicative, so how did we also make lists an instance of Applicative in this second way? If you remember, we said that the ZipList a type was introduced for this reason, which has one value constructor, ZipList, that has just one field. We put the list that we're wrapping in that field. Then, ZipList was made an instance of Applicative, so that when we want to use lists as applicatives in the zipping manner, we just wrap them with the ZipList constructor and then once we're done, unwrap them with getZipList:
ghci> getZipList $ ZipList [(+1),(*100),(*5)] <*> ZipList [1,2,3] [2,200,15]
So, what does this have to do with this newtype keyword? Well, think about how we might write the data declaration for our ZipList a type. One way would be to do it like so:
data ZipList a = ZipList [a]
A type that has just one value constructor and that value constructor has just one field that is a list of things. We might also want to use record syntax so that we automatically get a function that extracts a list from a ZipList:
data ZipList a = ZipList { getZipList :: [a] }
This looks fine and would actually work pretty well. We had two ways of making an existing type an instance of a type class, so we used the data keyword to just wrap that type into another type and made the other type an instance in the second way.
The newtype keyword in Haskell is made exactly for these cases when we want to just take one type and wrap it in something to present it as another type. In the actual libraries, ZipList a is defined like this:
newtype ZipList a = ZipList { getZipList :: [a] }
Instead of the data keyword, the newtype keyword is used. Now why is that? Well for one, newtype is faster. If you use the data keyword to wrap a type, there's some overhead to all that wrapping and unwrapping when your program is running. But if you use newtype, Haskell knows that you're just using it to wrap an existing type into a new type (hence the name), because you want it to be the same internally but have a different type. With that in mind, Haskell can get rid of the wrapping and unwrapping once it resolves which value is of what type.
So why not just use newtype all the time instead of data then? Well, when you make a new type from an existing type by using the newtype keyword, you can only have one value constructor and that value constructor can only have one field. But with data, you can make data types that have several value constructors and each constructor can have zero or more fields:
data Profession = Fighter | Archer | Accountant data Race = Human | Elf | Orc | Goblin data PlayerCharacter = PlayerCharacter Race Profession
When using newtype, you're restricted to just one constructor with one field.
We can also use the deriving keyword with newtype just like we would with data. We can derive instances for Eq, Ord, Enum, Bounded, Show and Read. If we derive the instance for a type class, the type that we're wrapping has to be in that type class to begin with. It makes sense, because newtype just wraps an existing type. So now if we do the following, we can print and equate values of our new type:
newtype CharList = CharList { getCharList :: [Char] } deriving (Eq, Show)
Let's give that a go:
ghci> CharList "this will be shown!" CharList {getCharList = "this will be shown!"} ghci> CharList "benny" == CharList "benny" True ghci> CharList "benny" == CharList "oisters" False
In this particular newtype, the value constructor has the following type:
CharList :: [Char] -> CharList
It takes a [Char] value, such as "my sharona" and returns a CharList value. From the above examples where we used the CharList value constructor, we see that really is the case. Conversely, the getCharList function, which was generated for us because we used record syntax in our newtype, has this type:
getCharList :: CharList -> [Char]
It takes a CharList value and converts it to a [Char] value. You can think of this as wrapping and unwrapping, but you can also think of it as converting values from one type to the other.
Using newtype to make type class instances
Many times, we want to make our types instances of certain type classes, but the type parameters just don't match up for what we want to do. It's easy to make Maybe an instance of Functor, because the Functor type class is defined like this:
class Functor f where fmap :: (a -> b) -> f a -> f b
So we just start out with:
instance Functor Maybe where
And then implement fmap. All the type parameters add up because the Maybe takes the place of f in the definition of the Functor type class and so if we look at fmap like it only worked on Maybe, it ends up behaving like:
fmap :: (a -> b) -> Maybe a -> Maybe b
Isn't that just peachy? Now what if we wanted to make the tuple an instance of Functor in such a way that when we fmap a function over a tuple, it gets applied to the first component of the tuple? That way, doing fmap (+3) (1,1) would result in (4,1). It turns out that writing the instance for that is kind of hard. With Maybe, we just say instance Functor Maybe where because only type constructors that take exactly one parameter can be made an instance of Functor. But it seems like there's no way to do something like that with (a,b) so that the type parameter a ends up being the one that changes when we use fmap. To get around this, we can newtype our tuple in such a way that the second type parameter represents the type of the first component in the tuple:
newtype Pair b a = Pair { getPair :: (a,b) }
And now, we can make it an instance of Functor so that the function is mapped over the first component:
instance Functor (Pair c) where fmap f (Pair (x,y)) = Pair (f x, y)
As you can see, we can pattern match on types defined with newtype. We pattern match to get the underlying tuple, then we apply the function f to the first component in the tuple and then we use the Pair value constructor to convert the tuple back to our Pair b a. If we imagine what the type fmap would be if it only worked on our new pairs, it would be:
fmap :: (a -> b) -> Pair c a -> Pair c b
Again, we said instance Functor (Pair c) where and so Pair c took the place of the f in the type class definition for Functor:
class Functor f where fmap :: (a -> b) -> f a -> f b
So now, if we convert a tuple into a Pair b a, we can use fmap over it and the function will be mapped over the first component:
ghci> getPair $ fmap (*100) (Pair (2,3)) (200,3) ghci> getPair $ fmap reverse (Pair ("london calling", 3)) ("gnillac nodnol",3)
On newtype laziness
We mentioned that newtype is usually faster than data. The only thing that can be done with newtype is turning an existing type into a new type, so internally, Haskell can represent the values of types defined with newtype just like the original ones, only it has to keep in mind that the their types are now distinct. This fact means that not only is newtype faster, it's also lazier. Let's take a look at what this means.
Like we've said before, Haskell is lazy by default, which means that only when we try to actually print the results of our functions will any computation take place. Furthemore, only those computations that are necessary for our function to tell us the result will get carried out. The undefined value in Haskell represents an erronous computation. If we try to evaluate it (that is, force Haskell to actually compute it) by printing it to the terminal, Haskell will throw a hissy fit (technically referred to as an exception):
ghci> undefined *** Exception: Prelude.undefined
However, if we make a list that has some undefined values in it but request only the head of the list, which is not undefined, everything will go smoothly because Haskell doesn't really need to evaluate any other elements in a list if we only want to see what the first element is:
ghci> head [3,4,5,undefined,2,undefined] 3
Now consider the following type:
data CoolBool = CoolBool { getCoolBool :: Bool }
It's your run-of-the-mill algebraic data type that was defined with the data keyword. It has one value constructor, which has one field whose type is Bool. Let's make a function that pattern matches on a CoolBool and returns the value "hello" regardless of whether the Bool inside the CoolBool was True or False:
helloMe :: CoolBool -> String helloMe (CoolBool _) = "hello"
Instead of applying this function to a normal CoolBool, let's throw it a curveball and apply it to undefined!
ghci> helloMe undefined "*** Exception: Prelude.undefined
Yikes! An exception! Now why did this exception happen? Types defined with the data keyword can have multiple value constructors (even though CoolBool only has one). So in order to see if the value given to our function conforms to the (CoolBool _) pattern, Haskell has to evaluate the value just enough to see which value constructor was used when we made the value. And when we try to evaluate an undefined value, even a little, an exception is thrown.
Instead of using the data keyword for CoolBool, let's try using newtype:
newtype CoolBool = CoolBool { getCoolBool :: Bool }
We don't have to change our helloMe function, because the pattern matching syntax is the same if you use newtype or data to define your type. Let's do the same thing here and apply helloMe to an undefined value:
ghci> helloMe undefined "hello"
It worked! Hmmm, why is that? Well, like we've said, when we use newtype, Haskell can internally represent the values of the new type in the same way as the original values. It doesn't have to add another box around them, it just has to be aware of the values being of different types. And because Haskell knows that types made with the newtype keyword can only have one constructor, it doesn't have to evaluate the value passed to the function to make sure that it conforms to the (CoolBool _) pattern because newtype types can only have one possible value constructor and one field!
This difference in behavior may seem trivial, but it's actually pretty important because it helps us realize that even though types defined with data and newtype behave similarly from the programmer's point of view because they both have value constructors and fields, they are actually two different mechanisms. Whereas data can be used to make your own types from scratch, newtype is for making a completely new type out of an existing type. Pattern matching on newtype values isn't like taking something out of a box (like it is with data), it's more about making a direct conversion from one type to another.
type vs. newtype vs. data
At this point, you may be a bit confused about what exactly the difference between type, data and newtype is, so let's refresh our memory a bit.
The type keyword is for making type synonyms. What that means is that we just give another name to an already existing type so that the type is easier to refer to. Say we did the following:
type IntList = [Int]
All this does is to allow us to refer to the [Int] type as IntList. They can be used interchangeably. We don't get an IntList value constructor or anything like that. Because [Int] and IntList are only two ways to refer to the same type, it doesn't matter which name we use in our type annotations:
ghci> ([1,2,3] :: IntList) ++ ([1,2,3] :: [Int]) [1,2,3,1,2,3]
We use type synonyms when we want to make our type signatures more descriptive by giving types names that tell us something about their purpose in the context of the functions where they're being used. For instance, when we used an association list of type [(String,String)] to represent a phone book, we gave it the type synonym of PhoneBook so that the type signatures of our functions were easier to read.
The newtype keyword is for taking existing types and wrapping them in new types, mostly so that it's easier to make them instances of certain type classes. When we use newtype to wrap an existing type, the type that we get is separate from the original type. If we make the following newtype:
newtype CharList = CharList { getCharList :: [Char] }
We can't use ++ to put together a CharList and a list of type [Char]. We can't even use ++ to put together two CharLists, because ++ works only on lists and the CharList type isn't a list, even though it could be said that it contains one. We can, however, convert two CharLists to lists, ++ them and then convert that back to a CharList.
When we use record syntax in our newtype declarations, we get functions for converting between the new type and the original type: namely the value constructor of our newtype and the function for extracting the value in its field. The new type also isn't automatically made an instance of the type classes that the original type belongs to, so we have to derive or manually write them.
In practice, you can think of newtype declarations as data declarations that can only have one constructor and one field. If you catch yourself writing such a data declaration, consider using newtype.
The data keyword is for making your own data types and with them, you can go hog wild. They can have as many constructors and fields as you wish and can be used to implement any algebraic data type by yourself. Everything from lists and Maybe-like types to trees.
If you just want your type signatures to look cleaner and be more descriptive, you probably want type synonyms. If you want to take an existing type and wrap it in a new type in order to make it an instance of a type class, chances are you're looking for a newtype. And if you want to make something completely new, odds are good that you're looking for the data keyword.
Monoids
Type classes in Haskell are used to present an interface for types that have some behavior in common. We started out with simple type classes like Eq, which is for types whose values can be equated, and Ord, which is for things that can be put in an order and then moved on to more interesting ones, like Functor and Applicative.
When we make a type, we think about which behaviors it supports, i.e. what it can act like and then based on that we decide which type classes to make it an instance of. If it makes sense for values of our type to be equated, we make it an instance of the Eq type class. If we see that our type is some kind of functor, we make it an instance of Functor, and so on.
Now consider the following: * is a function that takes two numbers and multiplies them. If we multiply some number with a 1, the result is always equal to that number. It doesn't matter if we do 1 * x or x * 1, the result is always x. Similarly, ++ is also a function which takes two things and returns a third. Only instead of multiplying numbers, it takes two lists and concatenates them. And much like *, it also has a certain value which doesn't change the other one when used with ++. That value is the empty list: [].
ghci> 4 * 1 4 ghci> 1 * 9 9 ghci> [1,2,3] ++ [] [1,2,3] ghci> [] ++ [0.5, 2.5] [0.5,2.5]
It seems that both * together with 1 and ++ along with [] share some common properties:
- The function takes two parameters.
- The parameters and the returned value have the same type.
- There exists such a value that doesn't change other values when used with the binary function.
There's another thing that these two operations have in common that may not be as obvious as our previous observations: when we have three or more values and we want to use the binary function to reduce them to a single result, the order in which we apply the binary function to the values doesn't matter. It doesn't matter if we do (3 * 4) * 5 or 3 * (4 * 5). Either way, the result is 60. The same goes for ++:
ghci> (3 * 2) * (8 * 5) 240 ghci> 3 * (2 * (8 * 5)) 240 ghci> "la" ++ ("di" ++ "da") "ladida" ghci> ("la" ++ "di") ++ "da" "ladida"
We call this property associativity. * is associative, and so is ++, but -, for example, is not. The expressions (5 - 3) - 4 and 5 - (3 - 4) result in different numbers.
By noticing and writing down these properties, we have chanced upon monoids! A monoid is when you have an associative binary function and a value which acts as an identity with respect to that function. When something acts as an identity with respect to a function, it means that when called with that function and some other value, the result is always equal to that other value. 1 is the identity with respect to * and [] is the identity with respect to ++. There are a lot of other monoids to be found in the world of Haskell, which is why the Monoid type class exists. It's for types which can act like monoids. Let's see how the type class is defined:
class Monoid m where mempty :: m mappend :: m -> m -> m mconcat :: [m] -> m mconcat = foldr mappend mempty
The Monoid type class is defined in import Data.Monoid. Let's take some time and get properly acquainted with it.
First of all, we see that only concrete types can be made instances of Monoid, because the m in the type class definition doesn't take any type parameters. This is different from Functor and Applicative, which require their instances to be type constructors which take one parameter.
The first function is mempty. It's not really a function, since it doesn't take parameters, so it's a polymorphic constant, kind of like minBound from Bounded. mempty represents the identity value for a particular monoid.
Next up, we have mappend, which, as you've probably guessed, is the binary function. It takes two values of the same type and returns a value of that type as well. It's worth noting that the decision to name mappend as it's named was kind of unfortunate, because it implies that we're appending two things in some way. While ++ does take two lists and append one to the other, * doesn't really do any appending, it just multiplies two numbers together. When we meet other instances of Monoid, we'll see that most of them don't append values either, so avoid thinking in terms of appending and just think in terms of mappend being a binary function that takes two monoid values and returns a third.
The last function in this type class definition is mconcat. It takes a list of monoid values and reduces them to a single value by doing mappend between the list's elements. It has a default implementation, which just takes mempty as a starting value and folds the list from the right with mappend. Because the default implementation is fine for most instances, we won't concern ourselves with mconcat too much from now on. When making a type an instance of Monoid, it suffices to just implement mempty and mappend. The reason mconcat is there at all is because for some instances, there might be a more efficient way to implement mconcat, but for most instances the default implementation is just fine.
Before moving on to specific instances of Monoid, let's take a brief look at the monoid laws. We mentioned that there has to be a value that acts as the identity with respect to the binary function and that the binary function has to be associative. It's possible to make instances of Monoid that don't follow these rules, but such instances are of no use to anyone because when using the Monoid type class, we rely on its instances acting like monoids. Otherwise, what's the point? That's why when making instances, we have to make sure they follow these laws:
- mempty `mappend` x = x
- x `mappend` mempty = x
- (x `mappend` y) `mappend` z = x `mappend` (y `mappend` z)
The first two state that mempty has to act as the identity with respect to mappend and the third says that mappend has to be associative i.e. that it the order in which we use mappend to reduce several monoid values into one doesn't matter. Haskell doesn't enforce these laws, so we as the programmer have to be careful that our instances do indeed obey them.
Lists are monoids
Yes, lists are monoids! Like we've seen, the ++ function and the empty list [] form a monoid. The instance is very simple:
instance Monoid [a] where mempty = [] mappend = (++)
Lists are an instance of the Monoid type class regardless of the type of the elements they hold. Notice that we wrote instance Monoid [a] and not instance Monoid [], because Monoid requires a concrete type for an instance.
Giving this a test run, we encounter no surprises:
ghci> [1,2,3] `mappend` [4,5,6] [1,2,3,4,5,6] ghci> ("one" `mappend` "two") `mappend` "tree" "onetwotree" ghci> "one" `mappend` ("two" `mappend` "tree") "onetwotree" ghci> "one" `mappend` "two" `mappend` "tree" "onetwotree" ghci> "pang" `mappend` mempty "pang" ghci> mconcat [[1,2],[3,6],[9]] [1,2,3,6,9] ghci> mempty :: [a] []
Notice that in the last line, we had to write an explicit type annotation, because if we just did mempty, GHCi wouldn't know which instance to use, so we had to say we want the list instance. We were able to use the general type of [a] (as opposed to specifying [Int] or [String]) because the empty list can act as if it contains any type.
Because mconcat has a default implementation, we get it for free when we make something an instance of Monoid. In the case of the list, mconcat turns out to be just concat. It takes a list of lists and flattens it, because that's the equivalent of doing ++ between all the adjecent lists in a list.
The monoid laws do indeed hold for the list instance. When we have several lists and we mappend (or ++) them together, it doesn't matter which ones we do first, because they're just joined at the ends anyway. Also, the empty list acts as the identity so all is well. Notice that monoids don't require that a `mappend` b be equal to b `mappend` a. In the case of the list, they clearly aren't:
ghci> "one" `mappend` "two" "onetwo" ghci> "two" `mappend` "one" "twoone"
And that's okay. The fact that for multiplication 3 * 5 and 5 * 3 are the same is just a property of multiplication, but it doesn't hold for all (and indeed, most) monoids.
Product and Sum
We already examined one way for numbers to be considered monoids. Just have the binary function be * and the identity value 1. It turns out that that's not the only way for numbers to be monoids. Another way is to have the binary function be + and the identity value 0:
ghci> 0 + 4 4 ghci> 5 + 0 5 ghci> (1 + 3) + 5 9 ghci> 1 + (3 + 5) 9
The monoid laws hold, because if you add 0 to any number, the result is that number. And addition is also associative, so we get no problems there. So now that there are two equally valid ways for numbers to be monoids, which way do choose? Well, we don't have to. Remember, when there are several ways for some type to be an instance of the same type class, we can wrap that type in a newtype and then make the new type an instance of the type class in a different way. We can have our cake and eat it too.
The Data.Monoid module exports two types for this, namely Product and Sum. Product is defined like this:
newtype Product a = Product { getProduct :: a } deriving (Eq, Ord, Read, Show, Bounded)
Simple, just a newtype wrapper with one type parameter along with some derived instances. Its instance for Monoid goes a little something like this:
instance Num a => Monoid (Product a) where mempty = Product 1 Product x `mappend` Product y = Product (x * y)
mempty is just 1 wrapped in a Product constructor. mappend pattern matches on the Product constructor, multiplies the two numbers and then wraps the resulting number back. As you can see, there's a Num a class constraint. So this means that Product a is an instance of Monoid for all a's that are already an instance of Num. To use Producta a as a monoid, we have to do some newtype wrapping and unwrapping:
ghci> getProduct $ Product 3 `mappend` Product 9 27 ghci> getProduct $ Product 3 `mappend` mempty 3 ghci> getProduct $ Product 3 `mappend` Product 4 `mappend` Product 2 24 ghci> getProduct . mconcat . map Product $ [3,4,2] 24
This is nice as a showcase of the Monoid type class, but no one in their right mind would use this way of multiplying numbers instead of just writing 3 * 9 and 3 * 1. But a bit later, we'll see how these Monoid instances that may seem trivial at this time can come in handy.
Sum is defined like Product and the instance is similar as well. We use it in the same way:
ghci> getSum $ Sum 2 `mappend` Sum 9 11 ghci> getSum $ mempty `mappend` Sum 3 3 ghci> getSum . mconcat . map Sum $ [1,2,3] 6
Any and All
Another type which can act like a monoid in two distinct but equally valid ways is Bool. The first way is to have the or function || act as the binary function along with False as the identity value. The way or works in logic is that if any of its two parameters is True, it returns True, otherwise it returns False. So if we use False as the identity value, it will return False when or-ed with False and True when or-ed with True. The Any newtype constructor is an instance of Monoid in this fashion. It's defined like this:
newtype Any = Any { getAny :: Bool } deriving (Eq, Ord, Read, Show, Bounded)
Its instance looks goes like so:
instance Monoid Any where mempty = Any False Any x `mappend` Any y = Any (x || y)
The reason it's called Any is because x `mappend` y will be True if any one of those two is True. Even if three or more Any wrapped Bools are mappended together, the result will hold True if any of them are True:
ghci> getAny $ Any True `mappend` Any False True ghci> getAny $ mempty `mappend` Any True True ghci> getAny . mconcat . map Any $ [False, False, False, True] True ghci> getAny $ mempty `mappend` mempty False
The other way for Bool to be an instance of Monoid is to kind of do the opposite: have && be the binary function and then make True the identity value. Logical and will return True only if both of its parameters are True. This is the newtype declaration, nothing fancy:
newtype All = All { getAll :: Bool } deriving (Eq, Ord, Read, Show, Bounded)
And this is the instance:
instance Monoid All where mempty = All True All x `mappend` All y = All (x && y)
When we mappend values of the All type, the result will be True only if all the values used in the mappend operations are True:
ghci> getAll $ mempty `mappend` All True True ghci> getAll $ mempty `mappend` All False False ghci> getAll . mconcat . map All $ [True, True, True] True ghci> getAll . mconcat . map All $ [True, True, False] False
Just like with multiplication and addition, we usually explicitly state the binary functions instead of wrapping them in newtypes and then using mappend and mempty. mconcat seems useful for Any and All, but usually it's easier to use the or and and functions, which take lists of Bools and return True if any of them are True or if all of them are True, respectively.
The Ordering monoid
Hey, remember the Ordering type? It's used as the result when comparing things and it can have three values: LT, EQ and GT, which stand for less than, equal and greater than respectively:
ghci> 1 `compare` 2 LT ghci> 2 `compare` 2 EQ ghci> 3 `compare` 2 GT
With lists, numbers and boolean values, finding monoids was just a matter of looking at already existing commonly used functions and seeing if they exhibit some sort of monoid behavior. With Ordering, we have to look a bit harder to recognize a monoid, but it turns out that its Monoid instance is just as intuitive as the ones we've met so far and also quite useful:
instance Monoid Ordering where mempty = EQ LT `mappend` _ = LT EQ `mappend` y = y GT `mappend` _ = GT
The instance is set up like this: when we mappend two Ordering values, the one on the left is kept, unless the value on the left is EQ, in which case the right one is the result. The identity is EQ. At first, this may seem kind of arbitrary, but it actually resembles the way we alphabetically compare words. We compare the first two letters and if they differ, we can already decide which word would go first in a dictionary. However, if the first two letters are equal, then we move on to comparing the next pair of letters and repeat the process.
For instance, if we were to alphabetically compare the words "ox" and "on", we'd first compare the first two letters of each word, see that they are equal and then move on to comparing the second letter of each word. We see that 'x' is alphabetically greater than 'n', and so we know how the words compare. To gain some intuition for EQ being the identity, we can notice that if we were to cram the same letter in the same position in both words, it wouldn't change their alphabetical ordering. "oix" is still alphabetically greater than and "oin".
It's important to note that in the Monoid instance for Ordering, x `mappend` y doesn't equal y `mappend` x. Because the first parameter is kept unless it's EQ, LT `mappend` GT will result in LT, whereas GT `mappend` LT will result in GT:
ghci> LT `mappend` GT LT ghci> GT `mappend` LT GT ghci> mempty `mappend` LT LT ghci> mempty `mappend` GT GT
OK, so how is this monoid useful? Let's say you were writing a function that takes two strings, compares their lengths, and returns an Ordering. But if the strings are of the same length, then instead of returning EQ right away, we want to compare them alphabetically. One way to write this would be like so:
lengthCompare :: String -> String -> Ordering lengthCompare x y = let a = length x `compare` length y b = x `compare` y in if a == EQ then b else a
We name the result of comparing the lengths a and the result of the alphabetical comparison b and then if it turns out that the lengths were equal, we return their alphabetical ordering.
But by employing our understanding of how Ordering is a monoid, we can rewrite this function in a much simpler manner:
import Data.Monoid lengthCompare :: String -> String -> Ordering lengthCompare x y = (length x `compare` length y) `mappend` (x `compare` y)
We can try this out:
ghci> lengthCompare "zen" "ants" LT ghci> lengthCompare "zen" "ant" GT
Remember, when we use mappend, its left parameter is always kept unless it's EQ, in which case the right one is kept. That's why we put the comparison that we consider to be the first, more important criterion as the first parameter. If we wanted to expand this function to also compare for the number of vowels and set this to be the second most important criterion for comparison, we'd just modify it like this:
import Data.Monoid lengthCompare :: String -> String -> Ordering lengthCompare x y = (length x `compare` length y) `mappend` (vowels x `compare` vowels y) `mappend` (x `compare` y) where vowels = length . filter (`elem` "aeiou")
We made a helper function, which takes a string and tells us how many vowels it has by first filtering it only for letters that are in the string "aeiou" and then applying length to that.
ghci> lengthCompare "zen" "anna" LT ghci> lengthCompare "zen" "ana" LT ghci> lengthCompare "zen" "ann" GT
Very cool. Here, we see how in the first example the lengths are found to be different and so LT is returned, because the length of "zen" is less than the length of "anna". In the second example, the lengths are the same, but the second string has more vowels, so LT is returned again. In the third example, they both have the same length and the same number of vowels, so they're compared alphabetically and "zen" wins.
The Ordering monoid is very cool because it allows us to easily compare things by many different criteria and put those criteria in an order themselves, ranging from the most important to the least.
Maybe the monoid
Let's take a look at the various ways that Maybe a can be made an instance of Monoid and what those instances are useful for.
One way is to treat Maybe a as a monoid only if its type parameter a is a monoid as well and then implement mappend in such a way that it uses the mappend operation of the values that are wrapped with Just. We use Nothing as the identity, and so if one of the two values that we're mappending is Nothing, we keep the other value. Here's the instance declaration:
instance Monoid a => Monoid (Maybe a) where mempty = Nothing Nothing `mappend` m = m m `mappend` Nothing = m Just m1 `mappend` Just m2 = Just (m1 `mappend` m2)
Notice the class constraint. It says that Maybe a is an instance of Monoid only if a is an instance of Monoid. If we mappend something with a Nothing, the result is that something. If we mappend two Just values, the contents of the Justs get mappended and then wrapped back in a Just. We can do this because the class constraint ensures that the type of what's inside the Just is an instance of Monoid.
ghci> Nothing `mappend` Just "andy" Just "andy" ghci> Just LT `mappend` Nothing Just LT ghci> Just (Sum 3) `mappend` Just (Sum 4) Just (Sum {getSum = 7})
This comes in use when you're dealing with monoids as results of computations that may have failed. Because of this instance, we don't have to check if the computations have failed by seeing if they're a Nothing or Just value; we can just continue to treat them as normal monoids.
But what if the type of the contents of the Maybe aren't an instance of Monoid? Notice that in the previous instance declaration, the only case where we have to rely on the contents being monoids is when both parameters of mappend are Just values. But if we don't know if the contents are monoids, we can't use mappend between them, so what are we to do? Well, one thing we can do is to just discard the second value and keep the first one. For this, the First a type exists and this is its definition:
newtype First a = First { getFirst :: Maybe a } deriving (Eq, Ord, Read, Show)
We take a Maybe a and we wrap it with a newtype. The Monoid instance is as follows:
instance Monoid (First a) where mempty = First Nothing First (Just x) `mappend` _ = First (Just x) First Nothing `mappend` x = x
Just like we said. mempty is just a Nothing wrapped with the First newtype constructor. If mappend's first parameter is a Just value, we ignore the second one. If the first one is a Nothing, then we present the second parameter as a result, regardless of whether it's a Just or a Nothing:
ghci> getFirst $ First (Just 'a') `mappend` First (Just 'b') Just 'a' ghci> getFirst $ First Nothing `mappend` First (Just 'b') Just 'b' ghci> getFirst $ First (Just 'a') `mappend` First Nothing Just 'a'
First is useful when we have a bunch of Maybe values and we just want to know if any of them is a Just. The mconcat function comes in handy:
ghci> getFirst . mconcat . map First $ [Nothing, Just 9, Just 10] Just 9
If we want a monoid on Maybe a such that the second parameter is kept if both parameters of mappend are Just values, Data.Monoid provides a the Last a type, which works like First a, only the last non-Nothing value is kept when mappending and using mconcat:
ghci> getLast . mconcat . map Last $ [Nothing, Just 9, Just 10] Just 10 ghci> getLast $ Last (Just "one") `mappend` Last (Just "two") Just "two"
Using monoids to fold data structures
One of the more interesting ways to put monoids to work is to make them help us define folds over various data structures. So far, we've only done folds over lists, but lists aren't the only data structure that can be folded over. We can define folds over almost any data structure. Trees especially lend themselves well to folding.
Because there are so many data structures that work nicely with folds, the Foldable type class was introduced. Much like Functor is for things that can be mapped over, Foldable is for things that can be folded up! It can be found in Data.Foldable and because it export functions whose names clash with the ones from the Prelude, it's best imported qualified (and served with basil):
import qualified Foldable as F
To save ourselves precious keystrokes, we've chosen to import it qualified as F. Alright, so what are some of the functions that this type class defines? Well, among them are foldr, foldl, foldr1 and foldl1. Huh? But we already know these functions, what's so new about this? Let's compare the types of Foldable's foldr and the foldr from the Prelude to see how they differ:
ghci> :t foldr foldr :: (a -> b -> b) -> b -> [a] -> b ghci> :t F.foldr F.foldr :: (F.Foldable t) => (a -> b -> b) -> b -> t a -> b
Ah! So whereas foldr takes a list and folds it up, the foldr from Data.Foldable accepts any type that can be folded up, not just lists! As expected, both foldr functions do the same for lists:
ghci> foldr (*) 1 [1,2,3] 6 ghci> F.foldr (*) 1 [1,2,3] 6
Okay then, what are some other data structures that support folds? Well, there's the Maybe we all know and love!
ghci> F.foldl (+) 2 (Just 9) 11 ghci> F.foldr (||) False (Just True) True
But folding over a Maybe value isn't terribly interesting, because when it comes to folding, it just acts like a list with one element if it's a Just value and as an empty list if it's Nothing. So let's examine a data structure that's a little more complex then.
Remember the tree data structure from the Making Our Own Types and Typeclasses chapter? We defined it like this:
data Tree a = Empty | Node a (Tree a) (Tree a) deriving (Show, Read, Eq)
We said that a tree is either an empty tree that doesn't hold any values or it's a node that holds one value and also two other trees. After defining it, we made it an instance of Functor and with that we gained the ability to fmap functions over it. Now, we're going to make it an instance of Foldable so that we get the abilty to fold it up. One way to make a type constructor an instance of Foldable is to just directly implement foldr for it. But another, often much easier way, is to implement the foldMap function, which is also a part of the Foldable type class. The foldMap function has the following type:
foldMap :: (Monoid m, Foldable t) => (a -> m) -> t a -> m
Its first parameter is a function that takes a value of the type that our foldable structure contains (denoted here with a) and returns a monoid value. Its second parameter is a foldable structure that contains values of type a. It maps that function over the foldable structure, thus producing a foldable structure that contains monoid values. Then, by doing mappend between those monoid values, it joins them all into a single monoid value. This function may sound kind of odd at the moment, but we'll see that it's very easy to implement. What's also cool is that implementing this function is all it takes for our type to be made an instance of Foldable. So if we just implement foldMap for some type, we get foldr and foldl on that type for free!
This is how we make Tree an instance of Foldable:
instance F.Foldable Tree where foldMap f Empty = mempty foldMap f (Node x l r) = F.foldMap f l `mappend` f x `mappend` F.foldMap f r
We think like this: if we are provided with a function that takes an element of our tree and returns a monoid value, how do we reduce our whole tree down to one single monoid value? When we were doing fmap over our tree, we applied the function that we were mapping to a node and then we recursively mapped the function over the left sub-tree as well as the right one. Here, we're tasked with not only mapping a function, but with also joining up the results into a single monoid value by using mappend. First we consider the case of the empty tree — a sad and lonely tree that has no values or sub-trees. It doesn't hold any value that we can give to our monoid-making function, so we just say that if our tree is empty, the monoid value it becomes is mempty.
The case of a non-empty node is a bit more interesting. It contains two sub-trees as well as a value. In this case, we recursively foldMap the same function f over the left and the right sub-trees. Remember, our foldMap results in a single monoid value. We also apply our function f to the value in the node. Now we have three monoid values (two from our sub-trees and one from applying f to the value in the node) and we just have to bang them together into a single value. For this purpose we use mappend, and naturally the left sub-tree comes first, then the node value and then the right sub-tree.
Notice that we didn't have to provide the function that takes a value and returns a monoid value. We receive that function as a parameter to foldMap and all we have to decide is where to apply that function and how to join up the resulting monoids from it.
Now that we have a Foldable instance for our tree type, we get foldr and foldl for free! Consider this tree:
testTree = Node 5 (Node 3 (Node 1 Empty Empty) (Node 6 Empty Empty) ) (Node 9 (Node 8 Empty Empty) (Node 10 Empty Empty) )
It has 5 at its root and then its left node is has 3 with 1 on the left and 6 on the right. The root's right node has a 9 and then an 8 to its left and a 10 on the far right side. With a Foldable instance, we can do all of the folds that we can do on lists:
ghci> F.foldl (+) 0 testTree 42 ghci> F.foldl (*) 1 testTree 64800
And also, foldMap isn't only useful for making new instances of Foldable; it comes in handy for reducing our structure to a single monoid value. For instance, if we want to know if any number in our tree is equal to 3, we can do this:
ghci> getAny $ F.foldMap (\x -> Any $ x == 3) testTree True
Here, \x -> Any $ x == 3 is a function that takes a number and returns a monoid value, namely a Bool wrapped in Any. foldMap applies this function to every element in our tree and then reduces the resulting monoids into a single monoid with mappend. If we do this:
ghci> getAny $ F.foldMap (\x -> Any $ x > 15) testTree False
All of the nodes in our tree would hold the value Any False after having the function in the lambda applied to them. But to end up True, mappend for Any has to have at least one True value as a parameter. That's why the final result is False, which makes sense because no value in our tree is greater than 15.
We can also easily turn our tree into a list by doing a foldMap with the \x -> [x] function. By first projecting that function onto our tree, each element becomes a singleton list. The mappend action that takes place between all those singleton list results in a single list that holds all of the elements that are in our tree:
ghci> F.foldMap (\x -> [x]) testTree [1,3,6,5,8,9,10]
What's cool is that all of these trick aren't limited to trees, they work on any instance of Foldable.