# Insert specific element y after every n elements in a list

I'm teaching myself Haskell and I've run across the question in my book that ask me to define a function insert that takes a positive integer `n`, element `y`, and a list `xs` that inserts the specified element `y` after every `n` elements in the list.

I believe pattern matching would probably be a good way to go but I've yet to really grasp what it means

``````insert :: Int -> Char -> [a] -> [a]
insert 0 y xs = xs
insert n y [] = []
insert n y (x:xs)
``````

An example of how the function should work:

``````insert 2 'X' "abcdefghijk" = "abXcdXefXghXijXk"
``````

I've taken care of the base cases at this point but I don't know how to proceed from here.

Any ideas? Thanks

-
`insert 2 'X' "abcdefghijk" = "abXcdXefXghXijXk"` I meant this (sorry i was typing fast) – NuNu Sep 30 '12 at 18:00

You can write a helper function that counts down and resets when it gets to zero.

``````insert :: Int -> a -> [a] -> [a]
insert n y xs = countdown n xs where
countdown 0 xs = y:countdown n xs -- reset to original n
countdown _ [] = []
countdown m (x:xs) = x:countdown (m-1) xs
``````

What behaviour do you want if it's time to insert at the end? Here I've prioritised inserting over finishing by putting `countdown 0 xs` before `countdown _ []`. How could you rewrite it if you wanted to skip the insert at the end?

Sample usage:

``````*Main> insert 3 '|' "Hello Mum, erm... can I borrow £20000 please?"
"Hel|lo |Mum|, e|rm.|.. |can| I |bor|row| £2|000|0 p|lea|se?|"
``````
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well this particular question asks for an element specifically a character. I ran your function and it throws me errors. Why is that? – NuNu Sep 30 '12 at 8:21
@NuNu What errors did you get? I'll paste a sample call in case that helps. – AndrewC Sep 30 '12 at 9:08
If you want it to only work with characters, you could change the type singature to be `insert :: Int -> Char -> [Char] -> [Char]`, which is the same as `insert :: Int -> Char -> String -> String`. – AndrewC Sep 30 '12 at 15:52
i see. thanks it makes a whole lot of sense now – NuNu Sep 30 '12 at 18:05

In the last case, take n elements of the list, insert a singleton list of y and then append the result of recursively calling the function after dropping first n elements of the list.

``````insert :: Int -> Char -> [a] -> [a]
insert 0 y xs = xs
insert n y [] = []
insert n y xs
| length xs < n = xs
| otherwise = take n xs ++ [y] ++ insert n y (drop n xs)
``````
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@AndrewC, given that the OP is just starting to learn Haskell, I think this answer is the simplest and hence best. – Abhinav Sarkar Sep 30 '12 at 8:06
It is simple, yes, and helpful. And `drop`, `take` and `length` are important functions to introduce to the OP. (I didn't downvote, by the way.) – AndrewC Sep 30 '12 at 8:08
@AndrewC Isn't this the okay direction for `(++)`? This should be no less efficient (asymptotically) than manually counting the way you suggested. `(++)` only gets really bad when it's associated to the left. – Daniel Wagner Sep 30 '12 at 8:12
Oooooops. I've let my own past mistakes mislead me - many years ago now, my second real-need haskell program analysed a vast number of polynomials for a property we were seeking for a research task. I used `++` the bad, left-associative way and ran out of memory on the department's biggest unix server before writing a line of data to the output files! Abhinav is not making the same mistake, you're right Daniel, so I deleted my original comment because it's wrong. I'm ashamed of myself. If I had a second upvote I would use it by way of apology. – AndrewC Sep 30 '12 at 9:02
The downvotes just keep coming without any reasons. What is wrong with this solution? It is correct, simple and it run in linear time which the best you can get. – Abhinav Sarkar Oct 1 '12 at 15:04

``````import Data.List

insertAtN n y xs = intercalate [y] . groups n \$ xs
where
groups n xs = takeWhile (not.null) . unfoldr (Just . splitAt n) \$ xs
``````

Of course if you insert `Char` into list of type `[a]` then `a` is `Char`, because in Haskell all elements of a list are of same type.

To help you understand this on a more immediate level, let's first look at just making a copy of a list:

``````copyList (x:xs) = x : copyList xs
copyList [] = []
``````

Now imagine you add index value to each element being copied (re-implementing `zip xs [1..]`):

``````copyIdxList xs = go 1 xs where
go i (x:xs) = (x,i) : go (i+1) xs
go _ [] = []
``````

Now that we have an index value when we're dealing with each element, we can use it and, say, put each 10-th element of a list twice into the result:

``````copyIdxTenthTwice xs = go 1 xs where
go i (x:xs) | i==10 = (x,i) : (x,i) : go 1 xs
go i (x:xs)         = (x,i) : go (i+1) xs
go _ [] = []
``````

See where I'm going with this? Instead of duplicating the `x`, you can insert `y` there. And you don't have to put the indices into the result.

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``````ins n y xs = zip xs (cycle [1..n]) >>= f where
f (x,k) = if k == n then [x,y] else [x]
``````

The `zip` part attaches cyclic "indexes" to the elements of the list, e.g. for `n = 3` and `xs = "abcdefg"` we get `[('a',1),('b',2)('c',3)('d',1)('e',2)('f',3)('g',1)]`. Now `(>>=)` (which is the same as `concatMap` in case of lists) uses `f` to map every pair back to the original element, except when we have the last index of a cycle: In that case we insert an additional divider element `y` as well.

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