Primitive Recursion If Then Else actually executing If Else Then

I have a problem with the projections in my definition of If Then Else. It's actually executing as If-Else-Then.

`````` import Prelude hiding (pred,and,or,not)

data PR = Z
| S
| P Int
| C PR [PR]
| PR PR PR
deriving Show
eval :: PR -> [Integer] - Integer
eval Z _ = 0
eval S [x] = x+1
eval (P n) xs = nth n xs
eval (C f gs) xs = eval f (map (\g -> eval g xs) gs)
eval (PR g h) (0:xs) = eval g xs
eval (PR g h) (x:xs) = eval h ((x-1) : eval (PR g h) ((x-1):xs) : xs)

nth _ [] = error "nth nil"
nth 0 _ = error "nth index"
nth 1 (x:_) = x
nth (n) (_:xs) = nth (n-1) xs

one = C S [Z]
plus = PR (P 1) (C S [P 2])
ife = PR (P 1) (C (P 2) [P 3, P 4])
``````

If I try swapping `P 3` and `P 4` it just breaks entirely (returns the 'then' value every time). `ite[0,2,3]` should return `3` and `ite[1,2,3]` should return `2`. Instead the opposite is happening. How can I correct this?

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Short identifiers can make code more readable, but... –  leftaroundabout Nov 26 '12 at 7:28
@leftaroundabout The identifiers follow the conventions used at my university for hand written PR proofs. –  evanmcdonnal Nov 26 '12 at 7:49

How are you liking this class? I noticed you and I have very similar homework assignments, Very similar.

Well First off you wanna make a Primitive recursive function that emulates the IF-Then-Else model. therefore,

``````eval ite [0,1,2] => 1
``````

and

``````eval ite [1,2,3] => 3
``````

and with what you provided, you seem to be getting a funtion with the same qualities yet in in the opposite instances depending on the first input.

`ife = PR (P 1) (C (P 2) [P 3, P 4])`

now what is your function saying? your ITE implementation uses the primitive recursion construct, that's a start, because in this you can split execution to two diffent expressions based on a condition. The same condition used in Boolean algegra. if 0 we have false, otherwise if a number evaluates to anything (0<), we have true. The PR construct does this by evaluating its first argument if the head of the "stack" is a 0, otherwise it evaluates its second argument in hopes that somewhere along the line it'll terminate (often time decrementing the head as your counter and eventually execution the first argument). But for all intents and purposes we can say that the second expression will be executed on (0<).

Phew! So, how do we fix your implementation!? Easy:

`ife = PR (P 2) (C (P 1) [P 3, P 4])`

We switch your two projections, as you simply had them backwards. If the head of the stack is Z, we want to project the second expression, otherwise we project the first. or better yet:

``````ite = PR (P 2) (P 1)
``````

I think, I'm not done with the homework either and if I'm wrong I would Highly appreciate any extra insight.

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Do you go to PSU? I bet that will be right but I can't check it til I'm done with work. I was too focused on `P 3` and `P 4`. After this I just have to do Factorial and Integer Equality. –  evanmcdonnal Nov 26 '12 at 17:45
Heh, CS 311. I have a feeling you were also in CS251 last spring. Here's a really cool hint: Since diff[2,1] == 1 and diff[1,2] == 0 you can construct the Absolute difference that combines these two equations: absDiff = C plus [(C minus [P1,P2]),(C minus [P2,P1])] this returns the difference no matter what order. It was not asked in the homework, but can be extremely useful in constructing the equality function. –  Eric Nov 27 '12 at 9:00
I finished the assignment a few hours ago. I did equality with `eq = C not [(C or [(C modus [P 1, P 2]), (C modus [P 2, P 1])]` it's pretty slick, maybe my favorite definition. –  evanmcdonnal Nov 27 '12 at 9:05

I think it should be

``````ife = PR (P 1) (C (P 2) [P 3, P 3])
^
``````

``````ife = PR (P 1) (C (P 2) [P 3, P 4])