# termination of finite lists

``````pp :: [a] -> [a]
pp list = case list of
[] -> []
(x: _) -> x : (qq list)

qq :: [a] -> [a]
qq list = case list of
[] -> []
(x: xs) -> (pp xs) ++ [x]
``````

Does the function pp terminate for finite lists? If so: how often are the functions pp and qq called in total if pp is called with a list of n elements? If pp does not terminate for finite lists, then why not.

I think the function pp will terminate, if pp is called with a list of n elements, pp and q will call 2n in total.

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Smells like homework... Did you try solving it yourself? – user529758 Jun 10 '13 at 6:02
Take a pen and paper and work through it with the list `[1, 2, 3, 4, 5]` and then you can tell us whether it terminates and a reasonable guess for the complexity – jozefg Jun 10 '13 at 14:26

One way to prove that a recursive calculation will terminate if the size of its input is (a) finite and (b) decreasing.

Let's look at `pp`

``````pp :: [a] -> [a]
pp list = case list of
[] -> []
(x: _) -> x : (qq list)
``````

The last line returns `x:qq list`, but the input was `list`, so it calls `qq` with the same length list.

Let's see what `qq` does:

``````qq :: [a] -> [a]
qq list = case list of
[] -> []
(x: xs) -> (pp xs) ++ [x]
``````

Here, we call `pp xs`, where we've matched `list` with the pattern `x:xs`. This means `x` is the head (first element) and `xs` is the tail (rest-of-list), so `xs` is one element shorter than the input, `list`.

This means that the length of the input decreases by one every time we call `qq` and doesn't decrease when we call `pp`. Hence you're right that there are a total number of 2n calls, which is of course finite, so the calculation terminates.

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