Haskell differentiates between *identifiers* and *operator symbols*. Identifiers are alphanumeric plus `'`

, and are valid terms on their own; if an identifier `prefix`

has a function type, you can thus call it as `prefix arg1 arg2`

. Operator names are sequences of symbols, and are called as `arg1 !&$ arg2`

.^{1} But sometimes, you want to use identifiers as infix operators or treat an infix operator as an identifier. Thus, if you surround any prefix function name with ```

s, it becomes an operator and you can (must) use it as infix: `arg1 `prefixFunc` arg2`

. And contrariwise, if you wrap an infix operator name in parentheses, it becomes syntactically valid on its own, and so can be called in prefix form: `(!&$) arg1 arg2`

.^{2}

When declaring a type signature for a variable, you need to give the variable's name *as an identifier*.^{3} For an ordinary function name like `xor`

, that's just the name; for an operator like `&&`

, you wrap it in parentheses, as discussed above, which is why you write `(&&) :: Bool -> Bool -> Bool`

. Thus, you'd write

```
xor :: Bool -> Bool -> Bool
True `xor` False = True
False `xor` True = True
True `xor` True = False
False `xor` False = False
```

Note that I had to make two changes. If you left off the backticks in the definition lines, it'll be as though you were trying to do pattern matching: `True`

would look like a constructor which took two arguments, and `xor`

would be the first one.^{4}

(Also, just for kicks, a shorter definition: `xor = (/=)`

:-))

^{1} The lexical structure is in §2.4

^{2} The expression structure is in §3.2.

^{3} The structure of type signatures is in §4.4.1, referring to the definition of *var* in §3.2.

^{4} The structure of bindings is in §4.4.3.