Understanding function composition with negate

After reading through a page on Higher Order Functions from an awesome site I am still having trouble understanding the negate function paired with function composition.

to be more specific, take this piece of code:

``````ghci> map (negate . sum . tail) [[1..5],[3..6],[1..7]]
``````

which yields:

``````[-14,-15,-27]
``````

I re-read the page again, but to be honest, I still have no idea how that line of code produced this answer, if someone could walk me through the process of this I would really appreciate it!

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You can just remove an arbitrary number of functions from the left of such a pipeline, to see what's going on. – leftaroundabout Jun 26 '13 at 18:35

``````map f [a,b,c] = [f a,  f b,  f c]
``````

because `map f (x:xs) = f x:map f xs` - apply `f` to each element of the list.

So

``````map (negate.sum.tail) [[1..5],[3..6],[1..7]]
= [(negate.sum.tail) [1..5],   (negate.sum.tail) [3..6],   (negate.sum.tail) [1..7]]
``````

now

``````(negate . sum . tail) [1..5]
= negate (sum (tail [1,2,3,4,5]))
= negate (sum  [2,3,4,5])
= negate 14
= -14
``````

because `(f.g) x = f (g x)` and `.` is right associative, so `(negate.sum.tail) xs = (negate.(sum.tail)) xs` which in turn is `negate ((sum.tail) xs) = negate (sum (tail xs))`.

`tail` gives you everything except the first element of a list: `tail (x:xs) = xs`, for example `tail "Hello" = "ello"` `sum` adds them up as you expect, and
`negate x = -x`.

The others work similarly, giving minus the sum of the tail of each list.

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I'm not sure calling `tail` the end of the list is fortunate. In other settings (Java, ...) "tail" is often used to denote the last node of a linked list, it might be better to use a wording that sets it clearer apart. Unfortunately, "all but the first element" is way too clumsy. – Daniel Fischer Jun 26 '13 at 18:36
@DanielFischer Cheers. Edited to make `tail` functionality more explicit. – AndrewC Jun 26 '13 at 18:39
Great. I won't bother to un- and re-upvote to show my appreciation, though. – Daniel Fischer Jun 26 '13 at 18:40
Very clear explanation. Thanks! – Syntactic Fructose Jun 26 '13 at 18:59
@Daniel Fischer this also confused me, as in C++ i always name the ending node of a linked list `tail`. – Syntactic Fructose Jun 27 '13 at 1:19

To add a different perspective to AndrewC's excellent answer I usually think about these types of problems in terms of the functor laws and `fmap`. Since `map` can be thought of as a specialization of `fmap` to lists we can replace `map` with the more general `fmap` and keep the same functionality:

``````ghci> fmap (negate . sum . tail) [[1..5],[3..6],[1..7]]
``````

Now we can apply the composition functor law using algebraic substitution to shift where the composition is happening and then map each function individually over the list:

``````fmap (f . g)  ==  fmap f . fmap g -- Composition functor law

fmap (negate . sum . tail)             \$ [[1..5],[3..6],[1..7]]
== fmap negate . fmap (sum . tail)     \$ [[1..5],[3..6],[1..7]]
== fmap negate . fmap sum . fmap tail  \$ [[1..5],[3..6],[1..7]]
== fmap negate . fmap sum \$    fmap tail [[1..5],[3..6],[1..7]]
== fmap negate . fmap sum              \$ [tail [1..5],tail [3..6],tail [1..7]] -- As per AndrewC's explanation
== fmap negate . fmap sum              \$ [[2..5],[4..6],[2..7]]
== fmap negate                         \$ [14, 15, 27]
==                                       [-14, -15, -27]
``````
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