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
```

reimplementing`map`

. Do you understand what`map`

does? Have you looked at its source code? – C. A. McCann Aug 23 '11 at 18:33`map`

a bit better. – C. A. McCann Aug 23 '11 at 19:02