# why is haskell interpreter giving me this parse error?

Doing exercises in Richard Bird's book "Introduction to Functional Programming Using Haskell," second edition. In the last line in the following code, I get the error "Parse error in pattern (n `times` Succ m). Note that the same pattern (with m and n interchanged) was accepted in the definition of `times`. Why am I getting this error?

``````    data Nat = Zero | Succ Nat
deriving (Eq, Ord, Show)

plus :: Nat -> Nat -> Nat
m `plus` Zero = m
m `plus` Succ n = Succ (m `plus` n)

m `times` Zero = Zero
m `times` Succ n = (m `times` n) `plus` m

divide :: Nat -> Nat -> Nat
Zero `divide` m = Zero
(n `times` Succ m) `divide` n = Succ m
``````
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Tip: I'm guessing Mr. Richard Bird expects you to make "divide" a total function (except for n divide Zero, of course) that ignores remainder. – Rodrigo_at_Ximera Dec 13 '12 at 23:15

You get a parse error on

``````(n `times` Succ m) `divide` n = Succ m
``````

because the arguments of the defined function must be patterns, that is

• a wildcard `_`
• a variable identifier `foo`
• a constructor application (a value constructor applied to as many patterns as its arity demands)
• a labelled pattern `F{field1 = value1, ..., fieldN = valueN}` (if the constructor `F` is defined using named field syntax)
• a literal `1`, `"foo"`
• a negative literal `-1`
• a tuple patter, `(1,2)`
• a list pattern `[1,2]`
• a parenthesised pattern `(pat)`, wher `pat` is a pattern
• a lazy pattern, `~pat`, where `pat` is a pattern

and the first argument here is not a pattern but a function application of a non-constructor function.

A pattern allows to deconstruct a value, but an ordinary function application doesn't. For your problem, if you have

``````12 `divide` 4
``````

-- and all that is available when the function is called is the value, not how it was obtained -- your attempted function definition would require that the compiler factors the value to check whether it can be written in the given form.

Another problem in that line is that you use the identifier `n` twice, but any variable identifier can only appear once in a pattern-match.

Note that the same pattern (with `m` and `n` interchanged) was accepted in the definition of `times`.

In the definition

``````m `times` Succ n = (m `times` n) `plus` m
``````

the function `times` is defined for some kinds of arguments. The entire left hand side is not a pattern, there we have the two patterns `m` - a variable pattern that matches every argument and binds it to the name `m` - and `Succ n` (that contains the nested variable pattern `n`).

The left hand side of the definition consists of the defined name (`times`) and two patterns for the arguments.

In the definition of `divide`, the same structure is expected, the name to be defined, and two patterns for the arguments.

``````(n `times` Succ m) `divide` n = Succ m
``````

So when the parser encounters the opening parenthesis, it expects a parenthesised pattern. But it finds

``````     n          `times`            Succ m
pattern infix-function-application pattern
``````

The top node of the expression tree of that is `times`, which is not a constructor. Hence the part between the parentheses cannot be parsed as a pattern.

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Thanks for the thoughtful and detailed answer. – restacker Dec 15 '12 at 20:30