You seem to prefer that we fix your code than start again, so
let's have a look at your code. Firstly, the main list chopping:

```
reverse (take i (reverse xs)) ++ reverse (drop i (reverse xs))
```

Now `reverse (take i (reverse xs))`

takes `i`

elements from the end of the list,
but you reverse the list twice to achieve this, and it would be better to do
`drop (length xs - i) xs`

. Similarly, you can implement `reverse (drop i (reverse xs)))`

as `take (length xs - i) xs`

. That gives us

```
drop (length xs - i) xs ++ take (length xs - i) xs
```

Now your code `\i->[1..n]<=n`

doesn't make sense because it compares the list `[1..n]`

with `n`

, which can't work. I think you're trying to make a loop where `i`

runs from
`1`

to `n`

, which is a good plan. Let's use a list comprehension to get the ones we wanted:

```
[drop (length xs - i) xs ++ take (length xs - i) xs | i <- [1 .. length xs], i <= n]
```

but now we're running from 1 to the length of the list but throwing away numbers above `n`

,
which would be better written

```
[drop (length xs - i) xs ++ take (length xs - i) xs | i <- [1..n]]
```

This does allow `n`

to be more than `length xs`

, but I don't see a big issue there, we could check that at first.

Notice now that we're only using `i`

in the form `(length xs - i)`

, and really we're recalculating
`length xs`

an awful lot more than we should, so instead of letting `i`

run from `1`

to `n`

, and using
`length xs - i`

, why don't we just have `j=length xs -i`

so `j`

runs from `length xs`

to `length xs - n`

:

```
[drop j xs ++ take j xs | j <- [length xs,length xs - 1 .. length xs - n]]
```

which works because for example `[6,5..1] == [6,5,4,3,2,1]`

It would be neater to do

```
let l = length xs in
[drop j xs ++ take j xs | j <- [l,l - 1 .. l - n]]
```

or maybe you like to `take`

more than you like to do arithmetic, so we could use:

```
let l = length xs in
take n [drop j xs ++ take j xs | j <- [l,l - 1 .. 0]]
```

which has the added benefit of stopping you doing too many, stopping
you when you get back to the start.

I'd rename your function from `generatingListforRightShifting`

to `rotationsR`

, giving

```
rotationsR n xs = let l = length xs in
take n [drop j xs ++ take j xs | j <- [l,l - 1 ..]]
```

Which gives `rotationsR 6 [1..4] == [[1,2,3,4],[4,1,2,3],[3,4,1,2],[2,3,4,1],[1,2,3,4]]`

.

Left rotation would look simpler:

```
rotationsL n xs = take n [drop j xs ++ take j xs | j <- [0..length xs]]
```

Digression: I couldn't help myself, sorry, and I started again.

I still don't like all that dropping and taking every single time, I'd rather pop
infinitely many copies of `xs`

next to each other (`cycle xs`

) and take infinitely
many `tails`

of that, chopping them all to the right length, but just give you the first n:

rotationsL' n xs = let l = length xs in
take n . map (take l) . tails . cycle $ xs

Because of lazy evaluation, only a finite amount of `cycle xs`

ever gets calculated,
but this one can run and run: `rotationsL' 10 [1..4]`

gives you:

```
[[1,2,3,4],[2,3,4,1],[3,4,1,2],[4,1,2,3],[1,2,3,4],[2,3,4,1],[3,4,1,2],[4,1,2,3],[1,2,3,4],[2,3,4,1]]
```

It would be nice to do the right roations that way too, but it doesn't work because
I'd need to start at the end of an infinite list and work my way back. Let's reuse
your reverse, take what you need, reverse trick again, though:

```
rotationsR' n xs = let l = length xs in
take n . map (reverse.take l) . tails . cycle . reverse $ xs
```

Undigression: If you'd rather stick more closely to your original code, you can do

```
generatingListforRightShifting n xs =
[reverse (take i (reverse xs)) ++ reverse (drop i (reverse xs)) | i <- [1..n]]
```