# Data types and non exhaustive patterns

If have a data type

``````data Arith  = Con Int
| Sub Arith Arith
| Mul Arith Arith
| Div Arith Arith
``````

an instance:

``````instance Show Arith where
show (Con i)     = show i
show (Add e1 e2) =  "(" ++ show e1 ++ " + " ++ show e2 ++ ")"
show (Sub e1 e2) =  "(" ++ show e1 ++ " - " ++ show e2 ++ ")"
show (Mul e1 e2) =  "(" ++ show e1 ++ " * " ++ show e2 ++ ")"
show (Div e1 e2) =  "(" ++ show e1 ++ " / " ++ show e2 ++ ")"
``````

and a function evaluate which is expected behave like:

``````ghci> eval (Mul (Con 5) (Div (Con 6) (Con 2) ))
15
``````

this is what I've come up with that's not working when I try anything more complex then the basic case.

``````eval :: ArithExp -> Int
eval (Con e1)                = e1
eval (Add (Con e1) (Con e2)) = e1 + e2
eval (Sub (Con e1) (Con e2)) = e1 - e2
eval (Div (Con e1) (Con e2)) = e1 `div` e2
eval (Mul (Con e1) (Con e2)) = e1 * e2
``````

When I try anything that isn't in this case, of course I get an error about exhaustive patterns.

So my question is, how do I catch all of the patterns without doing it the naive way?

I did notice that Add is defined as Add Arith Arith, Sub Arith Arith so how would I take advantage of that in my eval function? I tried doing:

``````eval (Add Arith Arith) = Arith + Arith
``````

But that didn't work either, (not in scope error).

You don't need to give me a full working code example or anything, I'm just trying to get pointed in the right direction. Still new at haskell.

Thanks.

-

You should use recursion.

``````eval (Add a1 a2) = (eval a1) + (eval a2)
``````

etc..

-
Ah ok, I'm not sure why I didn't think about that. I'm so new at haskell that I don't automatically think recursively. Something I need to work on. This works and from what I understand the base case is just eval (Con i) = i – Harrison Sep 25 '13 at 18:06

Here is a little refactoring to reduce duplication:

``````data OpT = Add | Sub | Mul | Div

data Arith  = Con Int
| Op OpT Arith Arith

eval :: Arith -> Int
eval (Con a) = a
eval (Op f a b) = evalOp f (eval a) (eval b) where
You can do the same with `show`.