I've accidently written a
Haskell Functors Tutorial
I'll answer your question using examples, and I'll put the types underneath in comments.
Watch out for the pattern in the types.
fmap is a generalisation of
Functors are for giving you the
fmap works like
map, so let's check out
map (subtract 1) [2,4,8,16] = [1,3,7,15]
-- Int->Int [Int] [Int]
So it uses the function
(subtract 1) inside the list. In fact, for lists,
fmap does exaclty what
map does. Let's multiply everything by 10 this time:
fmap (* 10) [2,4,8,16] = [10,40,80,160]
-- Int->Int [Int] [Int]
I'd describe this as mapping the function that multiplies by 10 over the list.
fmap also works on
What else can I
fmap over? Let's use the Maybe data type, which has two types of values,
Just x. (You can use
Nothing to represent a failure to get an answer while
Just x represents an answer.)
fmap (+7) (Just 10) = Just 17
fmap (+7) Nothing = Nothing
-- Int->Int Maybe Int Maybe Int
OK, so again,
fmap is using
(+7) inside the Maybe.
And we can fmap other functions too.
length finds the length of a list, so we can fmap it over
fmap length Nothing = Nothing
fmap length (Just [5.0, 4.0, 3.0, 2.0, 1.573458]) = Just 5
-- [Double]->Int Maybe [Double] Maybe Int
length :: [a] -> Int but I'm using it here on
[Double] so I specialised it.
show to turn stuff into strings. Secretly the actual type of
Show a => a -> String, but that's a bit long, and I'm using it here on an
Int, so it specialises to
Int -> String.
fmap show (Just 12) = Just "12"
fmap show Nothing = Nothing
-- Int->String Maybe Int Maybe String
also, looking back to lists
fmap show [3,4,5] = ["3", "4", "5"]
-- Int->String [Int] [String]
fmap works on
Let's use it on a slightly different structure,
Either. Values of type
Either a b are either
Left a values or
Right b values. Sometimes we use Either to represent a success
Right goodvalue or failure
Left errordetails, and sometime just to mix together values of two types into one. Anyway, the functor for the Either data type only works on the
Right - it leaves
Left values alone. That makes sense particularly if you're using Right values as the successful ones (and in fact we wouldn't be able to make it work on both because the types aren't necessarily the same). Lets use the type
Either String Int as an example
fmap (5*) (Left "hi") = Left "hi"
fmap (5*) (Right 4) = Right 20
-- Int->Int Either String Int Either String Int
(5*) work inside the Either, but for Eithers, only the
Right values get changed. But we can do it the other way round on
Either Int String, as long as the function works on strings. Let's put
", cool!" at the end of stuff, using
(++ ", cool!").
fmap (++ ", cool!") (Left 4) = Left 4
fmap (++ ", cool!") (Right "fmap edits values") = Right "fmap edits values, cool!"
-- String->String Either Int String Either Int String
It's especially cool to use
fmap on IO
Now one of my favourite ways of using fmap is to use it on
IO values to edit the value some IO operation gives me. Let's make an example that lets you type something in and then prints it out straight away:
echo1 :: IO ()
echo1 = do
putStrLn "Say something!"
whattheysaid <- getLine -- getLine :: IO String
putStrLn whattheysaid -- putStrLn :: String -> IO ()
We can write that in a way that feels neater to me:
echo2 :: IO ()
echo2 = putStrLn "Say something"
>> getLine >>= putStrLn
>> does one thing after another, but the reason I like this is because
>>= takes the String that
getLine gave us and fed it to
putStrLn which takes a String.
What if we wanted to just greet the user:
greet1 :: IO ()
greet1 = do
putStrLn "What's your name?"
name <- getLine
putStrLn ("Hello, " ++ name)
If we wanted to write that in the neater way I'm a bit stuck. I'd have to write
greet2 :: IO ()
greet2 = putStrLn "What's your name?"
>> getLine >>= (\name -> putStrLn ("Hello, " ++ name))
which is not nicer than the
do version. In fact the
do notation is there so you don't have to do this. But can
fmap come to the rescue? Yes it can.
("Hello, "++) is a function that I can fmap over the getLine!
fmap ("Hello, " ++) getLine = -- read a line, return "Hello, " in front of it
-- String->String IO String IO String
we can use it like this:
greet3 :: IO ()
greet3 = putStrLn "What's your name?"
>> fmap ("Hello, "++) getLine >>= putStrLn
We can pull this trick on anything we're given. Let's disagree with whether "True" or "False" was typed in:
fmap not readLn = -- read a line that has a Bool on it, change it
-- Bool->Bool IO Bool IO Bool
Or let's just report the size of a file:
fmap length (readFile "test.txt") = -- read the file, return its length
-- String->Int IO String IO Int
-- [a]->Int IO [Char] IO Int (more precisely)
Conclusions: What does
fmap do, and what does it do it to?
If you've been watching the patterns in the types and thinking about the examples you'll have noticed that fmap takes a function that works on some values, and applies that function on something that has or produces those values somehow, editing the values. (eg readLn was to read Bool, so had type
IO Bool there's a Boolean value in it in the sense that it produces a
Ints in it.)
fmap :: (a -> b) -> Something a -> Something b
this works for Something being List-of (written
IO and loads of over things. We call it a Functor if this works in a sensible way (there are some rules - later). The actual type of fmap is
fmap :: Functor something => (a -> b) -> something a -> something b
but we usually replace
f for brevity. It's all the same to the compiler, though:
fmap :: Functor f => (a -> b) -> f a -> f b
Have a look back at the types and check this always works - thing about
Either String Int carefully - what's
f that time?
Appendix: What are the Functor rules, and why do we have them?
id is the identity function:
id :: a -> a
id x = x
Here are the rules:
fmap id == id -- identity identity
fmap (f . g) == fmap f . fmap g -- composition
Firstly the identity identity: If you map the function that does nothing, that doesn't change anything. That sounds obvious (a lot of rules do), but you can interpret that as saying that
fmap is only allowed to change the values, not the structure.
fmap isn't allowed to turn
Just 4 into
Right 4 into
Left 4 because more than just the data changed - the structure or context for that data changed.
I hit this rule once when I was working on a graphical user interface project - I wanted to be able to edit the values, but I couldn't do it without changing the structure underneath. No-one would have really noticed the difference because it had the same effect, but realising it didn't obey the functor rules made me rethink my whole design, and it's much cleaner, slicker and faster now.
Secondly the composition: this means you can choose whether to fmap one function at a time, or fmap them both at the same time. If
fmap leaves the structure/context of your values alone and just edits them with the function its given, it will work with this rule too.
Why do we have them? To make sure
fmap doesn't sneakily do anything behind the scenes or change anything we didn't expect. They're not enforced by the compiler (asking the compiler to prove a theorem before it compiles your code isn't fair, and would slow compilation down - the programmer should check). This means you can cheat, but that's a bad plan because your code can give unexpected results.