# Mapping with pairs

I'm really new to Haskell and I'm stuck on trying to map the first item of each pair in a list.

Obviously this works:

``````map :: (a -> b) -> [a] -> [b]
map f xs = [f x | x <- xs]
``````

But how do I get it to work for

``````map :: (a -> b) -> [(a, Int)] -> [b]
``````

I just want it to ignore the Int values for now and apply f to a like it does in the first example. I've been trying for ages now so thanks for any help.

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thanks so much, it's working – user1131194 Jan 5 '12 at 2:25
If an answer helped you, please click the tick mark next to it to mark it as accepted :) – ehird Jan 5 '12 at 2:27

Well, assuming you don't want to use the build-in function `map`, starting from this:

``````map :: (a -> b) -> [a] -> [b]
map f xs = [f x | x <- xs]
``````

To accept a list of type `[(a, Int)]` and use just the `a`, you can pattern match the tuple:

``````map :: (a -> b) -> [(a, Int)] -> [b]
map f xs = [f x | (x, y) <- xs]
``````

If you want to keep the `Int`, you can put it back together afterwards:

``````map :: (a -> b) -> [(a, Int)] -> [(b, Int)]
map f xs = [(f x, y) | (x, y) <- xs]
``````

But all of this is a bit redundant. You can do the same by changing the argument to the original, generic `map`:

``````map :: (a -> b) -> [a] -> [b]
map f xs = [f x | x <- xs]

mapFst :: (a -> b) -> [(a, Int)] -> [b]
mapFst f xs = map (f . fst) xs

mapOnFirst :: (a -> b) -> [(a, Int)] -> [(b, Int)]
mapOnFirst f xs = map (\(x,y) -> (f x, y)) xs
``````

For the third version, the standard library's module `Control.Arrow` gives you a function called `first` that can be used to get the same effect:

``````mapOnFirst :: (a -> b) -> [(a, Int)] -> [(b, Int)]
mapOnFirst f xs = map (first f) xs
``````

Neat, huh?

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+1, but the question has `(a -> b) -> [(a, Int)] -> [b]`, not `(a -> b) -> [(a, Int)] -> [(b, Int)]`. – ehird Jan 5 '12 at 2:20
@ehird: Yeah, but the question mentioned ignoring the `Int` values "for now" so it seemed useful to include both versions while I was at it. – C. A. McCann Jan 5 '12 at 2:55
Ah, didn't realise you had `mapFst` in there. – ehird Jan 5 '12 at 2:56
just wondering what the \ is used for in the first mapOnFirst example? – user1131194 Jan 5 '12 at 3:07
@user1131194: Oh, sorry--it's a lambda expression, it creates an anonymous function. So `\(x,y) -> (y, x)` would be equivalent to `swap (x, y) = (y, x)`, except you don't have to declare it. – C. A. McCann Jan 5 '12 at 3:10
``````mapfst :: (a -> b) -> [(a, c)] -> [b]
mapfst f = map f . map fst
``````

Read from right to left: the `map fst` extracts all the first values, then the `map f` applies the function to each first value.

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+1, but `map (f . fst)` is better (especially if you want to examine the Int in future). – ehird Jan 5 '12 at 2:15
`mapFirst :: (a -> b) -> [(a,c)] -> [(b,c)]; mapFirst = map . first`, inspired by semantic editor combinators, is a similar function to think about. – Dan Burton Jan 5 '12 at 2:27
@ehird - how is that better, and what does that have to do with examining the `snd` part of the tuple? I thought `map foo . map bar` could always be optimized into `map (foo . bar)` with no performance difference except 1 pass instead of 2 over the list. – Dan Burton Jan 5 '12 at 2:31
@DanBurton: It's not about optimisation; if you have `map (f . fst)`, you only have to change one localised place in the source code (`f . fst`), not two (`f` and `. map fst`); it isolates the discarding of the second element so the behaviour can be more easily changed later (per the question: "I just want it to ignore the Int values for now", emphasis mine). But yes, I think GHC's `RULE` pragmas should always optimise `map f . map g` into `map (f . g)`. – ehird Jan 5 '12 at 2:34

A straightforward extension of what you already have, using list comprehensions:

``````map' :: (a -> b) -> [(a, Int)] -> [b]
map' f xs = [ f x | (x, _) <- xs ]
``````
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