You are quite close. We can in fact easily derive the type of `something`

by using a "*hole*" (`_`

) in `ghci`

:

```
Prelude Data.Either> :{
Prelude Data.Either| inExpr :: Either Int (Op,(Expr,Expr)) -> Expr
Prelude Data.Either| inExpr = either Num _
Prelude Data.Either| :}
<interactive>:36:21: error:
• Found hole: _ :: (Op, (Expr, Expr)) -> Expr
• In the second argument of ‘either’, namely ‘_’
In the expression: either Num _
In an equation for ‘inExpr’: inExpr = either Num _
• Relevant bindings include
inExpr :: Either Int (Op, (Expr, Expr)) -> Expr
(bound at <interactive>:36:1)
```

So we know that this function `_`

will need to have as type `(Op, (Expr, Expr)) -> Expr`

.

We can for example use a lambda-expression here:

```
inExpr :: Either Int (Op,(Expr,Expr)) -> Expr
inExpr = either Num
```**(\(o, (l, r)) -> Bop l o r)**

We thus "unpack" the tuple and the subtuple with a `(o, (l, r))`

pattern, and then construct an `Expr`

by using the `Bop`

data constructor, with `l`

, `o`

and `r`

as arguments.

That being said, simple pattern matching, for example in the head of the fucntion, will do the trick as well, and is perhaps easier to understand:

```
inExpr :: Either Int (Op,(Expr,Expr)) -> Expr
inExpr (Left a) = Num a
inExpr (Right (o, (l, r))) = Bop l o r
```

`something`

? – Willem Van Onsem May 10 at 10:51`either Num (uncurry ((`ap` snd) . (. fst) . flip Bop))`

, what's the problem? :) (Courtesy of pointfree.io.) – chepner May 11 at 13:50