# Haskell: Map function with tuples

I have to write a Haskell program that does the following:

``````Main> dotProduct [(1,3),(2,5),(3,3)]  2
[(2,3),(4,5),(6,3)]
``````

I have to do it both with and without `map` function. I already did it without `map`, but I have no clue to do it with `map`.

My `dotProduct` without `map` function:

``````dotProduct :: [(Float, Integer)] -> Float -> [(Float, Integer)]
dotProduct [] _ = []
dotProduct [(x,y)] z = [(x*z,y)]
dotProduct ((x,y):xys) z = (x*z,y):dotProduct (xys) z
``````

So I really need help with the `map` version.

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About half the code in the version you gave is just reimplementing `map`. Do you understand what `map` does? Have you looked at its source code? –  C. A. McCann Aug 23 '11 at 18:33
Well, i have done a few simple elemental problems using Map... And that's all i know about it. So you're right, i need a deeper knowledge of it. –  Valeria Aug 23 '11 at 18:58
I certainly encourage it. Most of the standard library functions in Haskell are very simple and easy to comprehend if you look at their implementations. Hopefully the worked example in my answer will help with understanding `map` a bit better. –  C. A. McCann Aug 23 '11 at 19:02
How about dotProduct x = map \$ first (*x) –  FUZxxl Aug 24 '11 at 5:47

EEVIAC already posted the answer, so I'll just explain how to come up with it yourself. As you probably know, `map` has the type signature `(a -> b) -> [a] -> [b]`. Now, `dotProduct` has the type `[(Float, Integer)] -> Float -> [(Float, Integer)]` and you'll call `map` somewhere in there, so it has to look something like this:

``````dotProduct theList z = map (??? z) theList
``````

where `???` is a function of type `Float -> (Float, Integer) -> (Float, Integer)` - this follows immediately from the type signature of `map` and from the fact that we pass `z` to the function, which we have to do, simply because there's no other place to use it in.

The thing with `map` and higher order functions in general is that you have to keep in mind what the higher order function does and "simply" supply it with the correct function. As `map` applies a given function to all elements in the list, your function only needs to work with one element, and you can forget all about the list - `map` will take care of it.

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Thanks for your clear and didactic explanation! –  Valeria Aug 23 '11 at 18:50

Rather than starting by trying to fit `map` in somehow, consider how you might simplify and generalize your current function. Starting from this:

``````dotProduct :: [(Float, Integer)] -> Float -> [(Float, Integer)]
dotProduct [] _ = []
dotProduct [(x,y)] z = [(x*z,y)]
dotProduct ((x,y):xys) z = (x*z,y):dotProduct (xys) z
``````

First, we'll rewrite the second case using the `(:)` constructor:

``````dotProduct ((x,y):[]) z = (x*z,y):[]
``````

Expanding the `[]` in the result using the first case:

``````dotProduct ((x,y):[]) z = (x*z,y):dotProduct [] z
``````

Comparing this to the third case, we can see that they're identical except for this being specialized for when `xys` is `[]`. So, we can simply eliminate the second case entirely:

``````dotProduct :: [(Float, Integer)] -> Float -> [(Float, Integer)]
dotProduct [] _ = []
dotProduct ((x,y):xys) z = (x*z,y):dotProduct (xys) z
``````

Next, generalizing the function. First, we rename it, and let `dotProduct` call it:

``````generalized :: [(Float, Integer)] -> Float -> [(Float, Integer)]
generalized [] _ = []
generalized ((x,y):xys) z = (x*z,y):generalized (xys) z

dotProduct :: [(Float, Integer)] -> Float -> [(Float, Integer)]
dotProduct xs z = generalized xs z
``````

First, we parameterize it by the operation, specializing to multiplication for `dotProduct`:

``````generalized :: (Float -> Float -> Float) -> [(Float, Integer)] -> Float -> [(Float, Integer)]
generalized _ [] _ = []
generalized f ((x,y):xys) z = (f x z,y):generalized f (xys) z

dotProduct :: [(Float, Integer)] -> Float -> [(Float, Integer)]
dotProduct xs z = generalized (*) xs z
``````

Next, we can observe two things: `generalized` doesn't depend on arithmetic directly anymore, so it can work on any type; and the only time `z` is used is as the second argument to `f`, so we can combine them into a single function argument:

``````generalized :: (a -> b) -> [(a, c)] -> [(b, c)]
generalized _ [] = []
generalized f ((x,y):xys) = (f x, y):generalized f (xys)

dotProduct :: [(Float, Integer)] -> Float -> [(Float, Integer)]
dotProduct xs z = generalized (* z) xs
``````

Now, we note that `f` is only used on the first element of a tuple. This sounds useful, so we'll extract that as a separate function:

``````generalized :: (a -> b) -> [(a, c)] -> [(b, c)]
generalized _ [] = []
generalized f (xy:xys) = onFirst f xy:generalized f (xys)

onFirst :: (a -> b) -> (a, c) -> (b, c)
onFirst f (x, y) = (f x, y)

dotProduct :: [(Float, Integer)] -> Float -> [(Float, Integer)]
dotProduct xs z = generalized (* z) xs
``````

Now we again observe that, in `generalized`, `f` is only used with `onFirst`, so we again combine them into a single function argument:

``````generalized :: ((a, c) -> (b, c)) -> [(a, c)] -> [(b, c)]
generalized _ [] = []
generalized f (xy:xys) = f xy:generalized f (xys)

dotProduct :: [(Float, Integer)] -> Float -> [(Float, Integer)]
dotProduct xs z = generalized (onFirst (* z)) xs
``````

And once again, we observe that `generalized` no longer depends on the list containing tuples, so we let it work on any type:

``````generalized :: (a -> b) -> [a] -> [b]
generalized _ [] = []
generalized f (x:xs) = f x : generalized f xs
``````

Now, compare the code for `generalized` to this:

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

It also turns out that a slightly more general version of `onFirst` also exists, so we'll replace both that and `generalized` with their standard library equivalents:

``````import Control.Arrow (first)

dotProduct :: [(Float, Integer)] -> Float -> [(Float, Integer)]
dotProduct xs z = map (first (* z)) xs
``````
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I'm amazed at your explanation!! I will read it carefully. Thank you very much for taking the trouble to write an answer like that! –  Valeria Aug 23 '11 at 19:24
``````dotProduct xs z = map (\(x,y) -> (x*z,y)) xs
``````

The `(\(x,y) -> (x*z,y))` part is a function which takes a pair and returns a new pair that's like the old one, except its first component is multiplied by `z`. The `map` function takes a function and applies it to each element in a list. So if we pass the `(\(x,y) -> (x*z,y))` function to `map`, it will apply that function to every element in `xs`.

Although are you sure your first one is correct? The dot product operation is usually defined so that it takes two vectors, multiplies corresponding component and then sums it all together. Like this:

``````dotProduct xs ys = sum \$ zipWith (*) xs ys
``````
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If you're answering a question that's explicitly homework, is it really so much to ask that you at least explain the answer, rather than just dropping a line of code and nothing else? –  C. A. McCann Aug 23 '11 at 18:34
You're right, haha, I'll add some explanation. –  EEVIAC Aug 23 '11 at 18:36
Thank you very much!! I always have troubles with lambda abstraction... And yes, the name "dotProduct" does not fit very well to the problem, but that is what is supposed to do. (Sorry for my English) –  Valeria Aug 23 '11 at 18:38