The type signature of `take`

is

```
take :: Int -> [a] -> [a]
```

Here's how you are using `take`

:

```
take (acc-1) (as' x (acc-1))
```

So we can conclude that

```
(acc-1) :: Int -- first parameter to `take`
acc :: Int -- therefore
(as' x (acc-1)) :: [a] -- second parameter to `take`, we don't know what `a` is
```

But your code says

```
as' :: Float -> Float -> Float
as' x acc = ...
```

From which we deduce

```
x :: Float -- first parameter to `as'`
acc :: Float -- second parameter to `as'`
(as' x (acc-1)) :: Float -- result of `as'`
```

Which leads to a couple of contradictions:

`acc`

cannot be an `Int`

and a `Float`

at the same time
`(as' x (acc-1))`

cannot be an `[a]`

and a `Float`

at the same time --- this is what the second error message is trying to tell you

Ultimately, you are trying to use `take`

on something that is not a list. I'm not sure what you are trying to do.

You probably intended to have the signature

```
as' :: Float -> Int -> [Float]
```

That should (I've not tested it) fix the type errors above, but still leaves a more fundamental problem: whenever you compute the *n*th element of the list, you compute the *n-1*th element of the list anew *twice* (and so on, back to the start of the list: exponential growth of recalculation), even though presumably this element has already been computed. There is no *sharing* going on.

e.g. consider

```
as' x acc = ( prev + (acc / prev) ) / 2 : as' x (acc+1)
where prev = last(take (acc-1) (as' x (acc-1)))
```

This is still inefficient: you still recompute previous elements of the list. But now you only recompute all previous elements once when computing the next element.

(It would also be remiss of me not to point out that `last(take (acc-1) (as' x (acc-1)))`

can be simplified to `(as' x (acc-1)) !! (acc-2)`

.)

The usual way to generate an infinite list where each element depends only on the previous element is to use `iterate`

.

The complication is that you have each element depending on an accumulator as well as depending on the previous element. We will get round that by incorporating the accumulator into each element of the list. When we are done we will throw away the accumulators to produce our final infinite list.

```
approxRoots :: Float -> [Float]
approxRoots x = map fst $ iterate next (x, 1)
-- I don't know what your initial approximation should be
-- I've put `x` but that's probably wrong
where next (prev, acc) = (prev + acc / prev, acc + 1)
-- First element of each pair is the approximation,
-- second element of each pair is the "accumulator" (actually an index)
-- I've probably transcribed your formula wrongly
```

`as'' start current = let next = (current + (start / current)) / 2 in current : (as'' start next)`

and then`as' x = as'' x x`

, although using iterate is a better idea – soulcheck Dec 21 '12 at 11:46