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I'm looking into how to implement Data.Map#map to apply a function f to each of a Data.Map's values.

Let's consider map' in Haskell on a List:

map' :: [a] -> (a -> b) -> [b]
map' [] _     = []
map' (x:xs) f = f x : map' xs f 

Note that I can pattern match on (x:xs) to recursively call map' xs f.

How can I pattern match to recursively apply f to each of Data.Map's values?

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Data.Map, by not exporting constructors, is specifically designed to prevent you from doing this. –  Dan Jun 11 at 2:08
    
Or, you could use ViewPatterns. –  Dan Jun 11 at 2:10
    
why does it prevent people from doing this? –  Kevin Meredith Jun 11 at 2:13
5  
So you can't do foolish things like manually construct unbalanced or mis-ordered trees. Is something wrong with just using fmap? Notice Map is an instance of many useful type classes. –  Thomas M. DuBuisson Jun 11 at 2:15
1  
@ThomasM.DuBuisson - I was trying to do this LYAH exercise: Try figuring out how Map k is made an instance of Functor by yourself!. I suppose that I don't need to implement Data.Map#map in order to do it, yea? –  Kevin Meredith Jun 11 at 2:23

2 Answers 2

While you can't write this yourself since Data.Map doesn't export constructors, we can cheat a little.

Specifically, if we pull up the source on github we can poke around a bit to see how exactly fmap is implemented.

The actual definition of Map is surprisingly simple

-- Ignore the !'s and UNPACK, it's telling GHC to do some clever things
-- with how strict the constructors are.
data Map k a  = Bin {-# UNPACK #-} !Size !k a !(Map k a) !(Map k a)
              | Tip

So a Map is either empty, Tip, or a branch, Bin, with a key, value, size, and two subchildren.

Size is also defined quite simply :)

type Size = Int

Now, on to the Functor instance! The precise definition is

instance Functor (Map k) where
  fmap f m = map f m

Now map is exactly what you would expect it to be

map :: (a -> b) -> Map k a -> Map k b
map _ Tip = Tip
map f (Bin sx kx x l r) = Bin sx kx (f x) (map f l) (map f r)

All we do is modify the value with f and then recurse. Trivial :)

Balancing and other tomfoolery don't need to happen here since we're only modifying the values in the tree, not the structure or keys on which it's ordered.

Now, since it'd defeat the point of the problem if you didn't write some code, why don't you implement fmap for a similar, simpler, structure

 data BinTree a = Node a (BinTree a) (BinTree a)
                | Leaf
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2  
This is a wonderful answer +1 –  luqui Jun 11 at 3:23

@jozefg's answer is very good. Do that. But every so often you really do want to break down data abstractions such as for Data.Map.Map, and it is in fact possible. You can use Template Haskell to access a module's internals, and the lens package actually provides everything that's necessary to accomplish it. I'm presenting this without commentary, because most of the time this is not what you should do.

{-# LANGUAGE TemplateHaskell #-}

module M where

import Data.Map as Map
import Control.Lens.TH
import Control.Lens

$(makePrisms ''Map)

mymap :: (a -> b) -> Map k a -> Map k b
mymap f inmap
    | Just () <- inmap ^? _Tip = review _Tip ()
    | Just (sz,k,a,l,r) <- inmap ^? _Bin =
        review _Bin (sz,k, f a, mymap f l, mymap f r)
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